Organic electroluminescent materials and devices

ABSTRACT

Provided are organometallic compounds including a ligand L A  having a structure of 
     
       
         
         
             
             
         
       
     
     Also provided are formulations comprising these organometallic compounds. Further provided are OLEDs and related consumer products that utilize these organometallic compounds.

This application claims priority under 35 U.S.C. § 119(e) to U.S. Provisional Application No. 63/088,378, filed on Oct. 6, 2020, the entire contents of which are incorporated herein by reference.

FIELD

The present disclosure generally relates to organometallic compounds and formulations and their various uses including as emitters in devices such as organic light emitting diodes and related electronic devices.

BACKGROUND

Opto-electronic devices that make use of organic materials are becoming increasingly desirable for various reasons. Many of the materials used to make such devices are relatively inexpensive, so organic opto-electronic devices have the potential for cost advantages over inorganic devices. In addition, the inherent properties of organic materials, such as their flexibility, may make them well suited for particular applications such as fabrication on a flexible substrate. Examples of organic opto-electronic devices include organic light emitting diodes/devices (OLEDs), organic phototransistors, organic photovoltaic cells, and organic photodetectors. For OLEDs, the organic materials may have performance advantages over conventional materials.

OLEDs make use of thin organic films that emit light when voltage is applied across the device. OLEDs are becoming an increasingly interesting technology for use in applications such as flat panel displays, illumination, and backlighting.

One application for phosphorescent emissive molecules is a full color display. Industry standards for such a display call for pixels adapted to emit particular colors, referred to as “saturated” colors. In particular, these standards call for saturated red, green, and blue pixels. Alternatively, the OLED can be designed to emit white light. In conventional liquid crystal displays emission from a white backlight is filtered using absorption filters to produce red, green and blue emission. The same technique can also be used with OLEDs. The white OLED can be either a single emissive layer (EML) device or a stack structure. Color may be measured using CIE coordinates, which are well known to the art.

SUMMARY

In one aspect, the present disclosure provides a compound comprising a ligand L_(A) having a structure of

wherein one of Z¹ and Z² is C and the other is N; each of K¹ or K² is independently a direct bond, O, or S; moiety B, moiety C, and moiety D are each independently monocyclic or polycyclic ring structure containing 5-membered or 6-membered carbocyclic or heterocyclic rings; X¹-X⁴ are each independently C or N, with at least one of X¹ or X² being N if both moiety B and moiety C of Formula I are monocyclic 6-membered aromatic rings; the maximum number of N atoms that can connect to each other within a ring is two; Y is selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; W is selected from the group consisting of O, S, S═O, SO₂, NR, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, GeRR′, PR, P═O, and P═S; each of R^(A), R^(B), R^(C), and R^(D) independently represents zero, mono, or up to the maximum allowed number of substitutions to its associated ring; each of R, R′, R^(A), R^(B), R^(C), and R^(D) is independently a hydrogen or a substituent selected from the group consisting of the general substituents defined herein; and any two adjacent R, R′, R^(A), R^(B), R^(C), or R^(D) can be joined or fused together to form a ring, wherein the ligand L_(A) is coordinated to a metal M by the two indicated dashed lines; wherein M is selected from the group consisting of Ru, Os, Ir, Pd, Pt, Cu, Ag, and Au; and wherein the ligand L_(A) can be joined with other ligands to form a tridentate, tetradentate, pentadentate, or hexadentate ligand.

In another aspect, the present disclosure provides a formulation of a compound comprising a ligand L_(A) having a structure of Formula I or Formula II as described herein.

In yet another aspect, the present disclosure provides an OLED having an organic layer comprising a compound comprising a ligand L_(A) having a structure of Formula I or Formula II as described herein.

In yet another aspect, the present disclosure provides a consumer product comprising an OLED with an organic layer comprising a compound comprising a ligand L_(A) having a structure of Formula I or Formula II as described herein.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an organic light emitting device.

FIG. 2 shows an inverted organic light emitting device that does not have a separate electron transport layer.

FIG. 3 shows photoluminescence spectrum of a representative compound of the present disclosure.

DETAILED DESCRIPTION A. Terminology

Unless otherwise specified, the below terms used herein are defined as follows:

As used herein, the term “organic” includes polymeric materials as well as small molecule organic materials that may be used to fabricate organic opto-electronic devices. “Small molecule” refers to any organic material that is not a polymer, and “small molecules” may actually be quite large. Small molecules may include repeat units in some circumstances. For example, using a long chain alkyl group as a substituent does not remove a molecule from the “small molecule” class. Small molecules may also be incorporated into polymers, for example as a pendent group on a polymer backbone or as a part of the backbone. Small molecules may also serve as the core moiety of a dendrimer, which consists of a series of chemical shells built on the core moiety. The core moiety of a dendrimer may be a fluorescent or phosphorescent small molecule emitter. A dendrimer may be a “small molecule,” and it is believed that all dendrimers currently used in the field of OLEDs are small molecules.

As used herein, “top” means furthest away from the substrate, while “bottom” means closest to the substrate. Where a first layer is described as “disposed over” a second layer, the first layer is disposed further away from substrate. There may be other layers between the first and second layer, unless it is specified that the first layer is “in contact with” the second layer. For example, a cathode may be described as “disposed over” an anode, even though there are various organic layers in between.

As used herein, “solution processable” means capable of being dissolved, dispersed, or transported in and/or deposited from a liquid medium, either in solution or suspension form.

A ligand may be referred to as “photoactive” when it is believed that the ligand directly contributes to the photoactive properties of an emissive material. A ligand may be referred to as “ancillary” when it is believed that the ligand does not contribute to the photoactive properties of an emissive material, although an ancillary ligand may alter the properties of a photoactive ligand.

As used herein, and as would be generally understood by one skilled in the art, a first “Highest Occupied Molecular Orbital” (HOMO) or “Lowest Unoccupied Molecular Orbital” (LUMO) energy level is “greater than” or “higher than” a second HOMO or LUMO energy level if the first energy level is closer to the vacuum energy level. Since ionization potentials (IP) are measured as a negative energy relative to a vacuum level, a higher HOMO energy level corresponds to an IP having a smaller absolute value (an IP that is less negative). Similarly, a higher LUMO energy level corresponds to an electron affinity (EA) having a smaller absolute value (an EA that is less negative). On a conventional energy level diagram, with the vacuum level at the top, the LUMO energy level of a material is higher than the HOMO energy level of the same material. A “higher” HOMO or LUMO energy level appears closer to the top of such a diagram than a “lower” HOMO or LUMO energy level.

As used herein, and as would be generally understood by one skilled in the art, a first work function is “greater than” or “higher than” a second work function if the first work function has a higher absolute value. Because work functions are generally measured as negative numbers relative to vacuum level, this means that a “higher” work function is more negative. On a conventional energy level diagram, with the vacuum level at the top, a “higher” work function is illustrated as further away from the vacuum level in the downward direction. Thus, the definitions of HOMO and LUMO energy levels follow a different convention than work functions.

The terms “halo,” “halogen,” and “halide” are used interchangeably and refer to fluorine, chlorine, bromine, and iodine.

The term “acyl” refers to a substituted carbonyl radical (C(O)—R_(s)).

The term “ester” refers to a substituted oxycarbonyl (—O—C(O)—R_(s) or —C(O)—O—R_(s)) radical.

The term “ether” refers to an —OR_(s) radical.

The terms “sulfanyl” or “thio-ether” are used interchangeably and refer to a —SR_(s) radical.

The term “selenyl” refers to a —SeR_(s) radical.

The term “sulfinyl” refers to a —S(O)—R_(s) radical.

The term “sulfonyl” refers to a —SO₂—R_(s) radical.

The term “phosphino” refers to a —P(R_(s))₃ radical, wherein each R_(s) can be same or different.

The term “silyl” refers to a —Si(R_(s))₃ radical, wherein each R_(s) can be same or different.

The term “germyl” refers to a —Ge(R_(s))₃ radical, wherein each R_(s) can be same or different.

The term “boryl” refers to a —B(R_(s))₂ radical or its Lewis adduct —B(R_(s))₃ radical, wherein R_(s) can be same or different.

In each of the above, R_(s) can be hydrogen or a substituent selected from the group consisting of deuterium, halogen, alkyl, cycloalkyl, heteroalkyl, heterocycloalkyl, arylalkyl, alkoxy, aryloxy, amino, silyl, alkenyl, cycloalkenyl, heteroalkenyl, alkynyl, aryl, heteroaryl, and combination thereof. Preferred R_(s) is selected from the group consisting of alkyl, cycloalkyl, aryl, heteroaryl, and combination thereof.

The term “alkyl” refers to and includes both straight and branched chain alkyl radicals. Preferred alkyl groups are those containing from one to fifteen carbon atoms and includes methyl, ethyl, propyl, 1-methylethyl, butyl, 1-methylpropyl, 2-methylpropyl, pentyl, 1-methylbutyl, 2-methylbutyl, 3-methylbutyl, 1,1-dimethylpropyl, 1,2-dimethylpropyl, 2,2-dimethylpropyl, and the like. Additionally, the alkyl group may be optionally substituted.

The term “cycloalkyl” refers to and includes monocyclic, polycyclic, and spiro alkyl radicals. Preferred cycloalkyl groups are those containing 3 to 12 ring carbon atoms and includes cyclopropyl, cyclopentyl, cyclohexyl, bicyclo[3.1.1]heptyl, spiro[4.5]decyl, spiro[5.5]undecyl, adamantyl, and the like. Additionally, the cycloalkyl group may be optionally substituted.

The terms “heteroalkyl” or “heterocycloalkyl” refer to an alkyl or a cycloalkyl radical, respectively, having at least one carbon atom replaced by a heteroatom. Optionally the at least one heteroatom is selected from O, S, N, P, B, Si and Se, preferably, O, S or N. Additionally, the heteroalkyl or heterocycloalkyl group may be optionally substituted.

The term “alkenyl” refers to and includes both straight and branched chain alkene radicals. Alkenyl groups are essentially alkyl groups that include at least one carbon-carbon double bond in the alkyl chain. Cycloalkenyl groups are essentially cycloalkyl groups that include at least one carbon-carbon double bond in the cycloalkyl ring. The term “heteroalkenyl” as used herein refers to an alkenyl radical having at least one carbon atom replaced by a heteroatom. Optionally the at least one heteroatom is selected from O, S, N, P, B, Si, and Se, preferably, O, S, or N. Preferred alkenyl, cycloalkenyl, or heteroalkenyl groups are those containing two to fifteen carbon atoms. Additionally, the alkenyl, cycloalkenyl, or heteroalkenyl group may be optionally substituted.

The term “alkynyl” refers to and includes both straight and branched chain alkyne radicals. Alkynyl groups are essentially alkyl groups that include at least one carbon-carbon triple bond in the alkyl chain. Preferred alkynyl groups are those containing two to fifteen carbon atoms. Additionally, the alkynyl group may be optionally substituted.

The terms “aralkyl” or “arylalkyl” are used interchangeably and refer to an alkyl group that is substituted with an aryl group. Additionally, the aralkyl group may be optionally substituted.

The term “heterocyclic group” refers to and includes aromatic and non-aromatic cyclic radicals containing at least one heteroatom. Optionally the at least one heteroatom is selected from O, S, N, P, B, Si, and Se, preferably, O, S, or N. Hetero-aromatic cyclic radicals may be used interchangeably with heteroaryl. Preferred hetero-non-aromatic cyclic groups are those containing 3 to 7 ring atoms which includes at least one hetero atom, and includes cyclic amines such as morpholino, piperidino, pyrrolidino, and the like, and cyclic ethers/thio-ethers, such as tetrahydrofuran, tetrahydropyran, tetrahydrothiophene, and the like. Additionally, the heterocyclic group may be optionally substituted.

The term “aryl” refers to and includes both single-ring aromatic hydrocarbyl groups and polycyclic aromatic ring systems. The polycyclic rings may have two or more rings in which two carbons are common to two adjoining rings (the rings are “fused”) wherein at least one of the rings is an aromatic hydrocarbyl group, e.g., the other rings can be cycloalkyls, cycloalkenyls, aryl, heterocycles, and/or heteroaryls. Preferred aryl groups are those containing six to thirty carbon atoms, preferably six to twenty carbon atoms, more preferably six to twelve carbon atoms. Especially preferred is an aryl group having six carbons, ten carbons or twelve carbons. Suitable aryl groups include phenyl, biphenyl, triphenyl, triphenylene, tetraphenylene, naphthalene, anthracene, phenalene, phenanthrene, fluorene, pyrene, chrysene, perylene, and azulene, preferably phenyl, biphenyl, triphenyl, triphenylene, fluorene, and naphthalene. Additionally, the aryl group may be optionally substituted.

The term “heteroaryl” refers to and includes both single-ring aromatic groups and polycyclic aromatic ring systems that include at least one heteroatom. The heteroatoms include, but are not limited to O, S, N, P, B, Si, and Se. In many instances, O, S, or N are the preferred heteroatoms. Hetero-single ring aromatic systems are preferably single rings with 5 or 6 ring atoms, and the ring can have from one to six heteroatoms. The hetero-polycyclic ring systems can have two or more rings in which two atoms are common to two adjoining rings (the rings are “fused”) wherein at least one of the rings is a heteroaryl, e.g., the other rings can be cycloalkyls, cycloalkenyls, aryl, heterocycles, and/or heteroaryls. The hetero-polycyclic aromatic ring systems can have from one to six heteroatoms per ring of the polycyclic aromatic ring system. Preferred heteroaryl groups are those containing three to thirty carbon atoms, preferably three to twenty carbon atoms, more preferably three to twelve carbon atoms. Suitable heteroaryl groups include dibenzothiophene, dibenzofuran, dibenzoselenophene, furan, thiophene, benzofuran, benzothiophene, benzoselenophene, carbazole, indolocarbazole, pyridylindole, pyrrolodipyridine, pyrazole, imidazole, triazole, oxazole, thiazole, oxadiazole, oxatriazole, dioxazole, thiadiazole, pyridine, pyridazine, pyrimidine, pyrazine, triazine, oxazine, oxathiazine, oxadiazine, indole, benzimidazole, indazole, indoxazine, benzoxazole, benzisoxazole, benzothiazole, quinoline, isoquinoline, cinnoline, quinazoline, quinoxaline, naphthyridine, phthalazine, pteridine, xanthene, acridine, phenazine, phenothiazine, phenoxazine, benzofuropyridine, furodipyridine, benzothienopyridine, thienodipyridine, benzoselenophenopyridine, and selenophenodipyridine, preferably dibenzothiophene, dibenzofuran, dibenzoselenophene, carbazole, indolocarbazole, imidazole, pyridine, triazine, benzimidazole, 1,2-azaborine, 1,3-azaborine, 1,4-azaborine, borazine, and aza-analogs thereof. Additionally, the heteroaryl group may be optionally substituted.

Of the aryl and heteroaryl groups listed above, the groups of triphenylene, naphthalene, anthracene, dibenzothiophene, dibenzofuran, dibenzoselenophene, carbazole, indolocarbazole, imidazole, pyridine, pyrazine, pyrimidine, triazine, and benzimidazole, and the respective aza-analogs of each thereof are of particular interest.

The terms alkyl, cycloalkyl, heteroalkyl, heterocycloalkyl, alkenyl, cycloalkenyl, heteroalkenyl, alkynyl, aralkyl, heterocyclic group, aryl, and heteroaryl, as used herein, are independently unsubstituted, or independently substituted, with one or more general substituents.

In many instances, the general substituents are selected from the group consisting of deuterium, halogen, alkyl, cycloalkyl, heteroalkyl, heterocycloalkyl, arylalkyl, alkoxy, aryloxy, amino, silyl, germyl, boryl, selenyl, alkenyl, cycloalkenyl, heteroalkenyl, alkynyl, aryl, heteroaryl, acyl, carboxylic acid, ether, ester, nitrile, isonitrile, sulfanyl, sulfinyl, sulfonyl, phosphino, and combinations thereof.

In some instances, the preferred general substituents are selected from the group consisting of deuterium, fluorine, alkyl, cycloalkyl, heteroalkyl, alkoxy, aryloxy, amino, silyl, boryl, alkenyl, cycloalkenyl, heteroalkenyl, aryl, heteroaryl, nitrile, isonitrile, sulfanyl, and combinations thereof.

In some instances, the preferred general substituents are selected from the group consisting of deuterium, fluorine, alkyl, cycloalkyl, alkoxy, aryloxy, amino, silyl, boryl, aryl, heteroaryl, sulfanyl, and combinations thereof.

In yet other instances, the more preferred general substituents are selected from the group consisting of deuterium, fluorine, alkyl, cycloalkyl, aryl, heteroaryl, and combinations thereof.

The terms “substituted” and “substitution” refer to a substituent other than H that is bonded to the relevant position, e.g., a carbon or nitrogen. For example, when R¹ represents mono-substitution, then one R¹ must be other than H (i.e., a substitution). Similarly, when R¹ represents di-substitution, then two of R¹ must be other than H. Similarly, when R¹ represents zero or no substitution, R¹, for example, can be a hydrogen for available valencies of ring atoms, as in carbon atoms for benzene and the nitrogen atom in pyrrole, or simply represents nothing for ring atoms with fully filled valencies, e.g., the nitrogen atom in pyridine. The maximum number of substitutions possible in a ring structure will depend on the total number of available valencies in the ring atoms.

As used herein, “combinations thereof” indicates that one or more members of the applicable list are combined to form a known or chemically stable arrangement that one of ordinary skill in the art can envision from the applicable list. For example, an alkyl and deuterium can be combined to form a partial or fully deuterated alkyl group; a halogen and alkyl can be combined to form a halogenated alkyl substituent; and a halogen, alkyl, and aryl can be combined to form a halogenated arylalkyl. In one instance, the term substitution includes a combination of two to four of the listed groups. In another instance, the term substitution includes a combination of two to three groups. In yet another instance, the term substitution includes a combination of two groups. Preferred combinations of substituent groups are those that contain up to fifty atoms that are not hydrogen or deuterium, or those which include up to forty atoms that are not hydrogen or deuterium, or those that include up to thirty atoms that are not hydrogen or deuterium. In many instances, a preferred combination of substituent groups will include up to twenty atoms that are not hydrogen or deuterium.

The “aza” designation in the fragments described herein, i.e. aza-dibenzofuran, aza-dibenzothiophene, etc. means that one or more of the C—H groups in the respective aromatic ring can be replaced by a nitrogen atom, for example, and without any limitation, azatriphenylene encompasses both dibenzo[f,h]quinoxaline and dibenzo[f,h]quinoline. One of ordinary skill in the art can readily envision other nitrogen analogs of the aza-derivatives described above, and all such analogs are intended to be encompassed by the terms as set forth herein.

As used herein, “deuterium” refers to an isotope of hydrogen. Deuterated compounds can be readily prepared using methods known in the art. For example, U.S. Pat. No. 8,557,400, Patent Pub. No. WO 2006/095951, and U.S. Pat. Application Pub. No. US 2011/0037057, which are hereby incorporated by reference in their entireties, describe the making of deuterium-substituted organometallic complexes. Further reference is made to Ming Yan, et al., Tetrahedron 2015, 71, 1425-30 and Atzrodt et al., Angew. Chem. Int. Ed. (Reviews) 2007, 46, 7744-65, which are incorporated by reference in their entireties, describe the deuteration of the methylene hydrogens in benzyl amines and efficient pathways to replace aromatic ring hydrogens with deuterium, respectively.

It is to be understood that when a molecular fragment is described as being a substituent or otherwise attached to another moiety, its name may be written as if it were a fragment (e.g. phenyl, phenylene, naphthyl, dibenzofuryl) or as if it were the whole molecule (e.g. benzene, naphthalene, dibenzofuran). As used herein, these different ways of designating a substituent or attached fragment are considered to be equivalent.

In some instance, a pair of adjacent substituents can be optionally joined or fused into a ring. The preferred ring is a five, six, or seven-membered carbocyclic or heterocyclic ring, includes both instances where the portion of the ring formed by the pair of substituents is saturated and where the portion of the ring formed by the pair of substituents is unsaturated. As used herein, “adjacent” means that the two substituents involved can be on the same ring next to each other, or on two neighboring rings having the two closest available substitutable positions, such as 2, 2′ positions in a biphenyl, or 1, 8 position in a naphthalene, as long as they can form a stable fused ring system.

B. The Compounds of the Present Disclosure

In one aspect, the present disclosure provides a compound comprising a ligand L_(A) having a structure of

wherein: one of Z¹ and Z² is C and the other is N; each of K¹ or K² is independently a direct bond, O, or S; moiety B, moiety C, and moiety D are each independently monocyclic or polycyclic ring structure containing 5-membered or 6-membered carbocyclic or heterocyclic rings; X¹-X⁴ are each independently C or N, with at least one of X¹ or X² being N if both moiety B and moiety C of Formula I are monocyclic 6-membered aromatic rings; the maximum number of N atoms that can connect to each other within a ring is two; Y is selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; W is selected from the group consisting of O, S, S═O, SO₂, NR, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, GeRR′, PR, P═O, and P═S; each of R^(A), R^(B), R^(C), and R^(D) independently represents zero, mono, or up to the maximum allowed number of substitutions to its associated ring; each of R, R′, R^(A), R^(B), R^(C), and R^(D) is independently a hydrogen or a substituent selected from the group consisting of the general substituents defined herein; and any two adjacent R, R′, R^(A), R^(B), R^(C), or R^(D) can be joined or fused together to form a ring, wherein the ligand L_(A) is coordinated to a metal M by the two indicated dashed lines; wherein M is selected from the group consisting of Ru, Os, Ir, Pd, Pt, Cu, Ag, and Au; and wherein the ligand L_(A) can be joined with other ligands to form a tridentate, tetradentate, pentadentate, or hexadentate ligand.

In some embodiments, each of R, R′, R^(A), R^(B), R^(C), and R^(D) can be independently a hydrogen or a substituent selected from the group consisting of deuterium, fluorine, alkyl, cycloalkyl, heteroalkyl, alkoxy, aryloxy, amino, silyl, boryl, alkenyl, cycloalkenyl, heteroalkenyl, aryl, heteroaryl, nitrile, isonitrile, sulfanyl, and combinations thereof.

In some embodiments, W can be O, S, NR, CRR′, BR, BRR′, or SiRR′. In some embodiments, Y can be O, S, NR, BR, or BRR′.

In some embodiments, X¹ can be C. In some embodiments, X² can be C. In some embodiments, one of X¹ and X² can be C and the other can be N. In some embodiments, X¹ and X² can be both C while one of moiety B or moiety C of Formula I can be a 5-membered ring. In some embodiments, X³ and X⁴ can be both C. In some embodiments, X³ can be C, and X⁴ can be N.

In some embodiments, ring A can be selected from the group consisting of benzene, pyridine, pyrimidine, pyridazine, and pyrazine. In some embodiments, moiety B can be a 5-membered or 6-membered aromatic ring. In some embodiments, moiety B can be benzene, pyridine, pyrimidine, pyridazine, pyrazine, imidazole, pyrazole, pyrrole, oxazole, furan, thiophene, thiazole, or triazole. In some embodiments, moiety D can be a 5-membered or 6-membered aromatic ring. In some embodiments, moiety D can be benzene, pyridine, pyrimidine, pyridazine, pyrazine, imidazole, pyrazole, pyrrole, oxazole, furan, thiophene, thiazole, or triazole. In some embodiments, moiety C each can be independently a monocyclic 5-membered or 6-membered aromatic ring. In some embodiments, the 5-membered or 6-membered aromatic ring can be benzene, pyridine, pyrimidine, pyridazine, pyrazine, imidazole, pyrazole, pyrrole, oxazole, furan, thiophene, thiazole, or triazole. In some embodiments, moiety C each can be independently a multicyclic ring structure containing a total of two, three, four, five, six or seven fused rings containing 5-membered and 6-membered aromatic rings. In some embodiments, the 5-membered and 6-membered aromatic rings can be selected from the group consisting of benzene, pyridine, pyrimidine, pyridazine, pyrazine, imidazole, pyrazole, pyrrole, oxazole, furan, thiophene, thiazole, and triazole.

In some embodiments, two adjacent R^(A) substituents can be joined to form a fused 5-membered or 6-membered ring. In some embodiments, one R^(A) substituent can be joined with one R or R′ of Y to form a ring when Y is NR, CRR′, BR, BRR′, or SiRR′. In some embodiments, two adjacent R^(B) substituents can be joined to form a fused 5-membered or 6-membered ring. In some embodiments, one substituent of the newly formed fused ring can be joined with one R^(A) substituent to form a ring. In some embodiments, one R^(B) substituent can be joined with one R or R′ of W to form a ring when W is NR, CRR′, SiRR′, BR, or BRR′. In some embodiments, two adjacent R^(C) substituents can be joined to form a fused ring. In some embodiments, one R^(C) substituent can be joined with one R or R′ of W to form a ring when W is NR, CRR′, SiRR′, BR, or BRR′. In some embodiments, two adjacent R^(D) substituents can be joined to form a fused ring. In some embodiments, one R^(D) substituent can be joined with one R or R′ of Y to form a ring when Y is NR, CRR′, BR, BRR′, or SiRR′. In some embodiments, one R^(D) substituent can be joined with one R or R′ of W to form a ring when W is NR, CRR′, SiRR′, BR, or BRR′.

In some embodiments, M can be Ir, Pd or Pt.

In some embodiments, the compound can further comprise a substituted or unsubstituted phenyl-pyridine ligand. In some embodiments, the compound can further comprise a substituted or unsubstituted acetylacetonate ligand.

In some embodiments, the ligand L_(A) can be selected from the group consisting of:

wherein X⁵, X⁶, and X⁷ are each independently C or N; Y² for each occurrence is independently selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; and each of ring A1 and ring B1 is independently a 5-membered or 6-membered carbocyclic or heterocyclic ring.

In some embodiments, the ligand L_(A) can be selected from the group consisting of the structures shown below in LIST 1:

wherein: X⁵-X¹⁰ are each independently N or C;

Y¹ is O, S, or Se;

Y² for each occurrence is independently selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; and R, R′, and the remaining variables are the same as previously defined.

In some embodiments, the ligand L_(A) can be selected from the group consisting of L_(Ai-m) wherein i is an integer from 1 to 1560, m is an integer 1 to 18, and based on formula L_(Ai-1) to L_(Ai-18); L_(Ai-m′) wherein i is an integer from 1 to 4420, m′ is an integer from 19 to 54, and based on formula L_(Ai-19) to L_(Ai-54); and L_(Ai′-m″) wherein i′ is an integer from 4421 to 4740, m″ is an integer from 55 to 69, and based on formula L_(Ai′-55) to L_(Ai′-69), wherein each structure of L_(Ai-1) through L_(Ai-54), and L_(Ai′-55) through L_(Ai′-69) is shown below in LIST 2:

wherein for each i in L_(Ai) and L_(Ai′), R^(E), G, and W are defined below:

i R^(E) G W 1 R¹ G¹¹ W¹ 2 R² G¹¹ W¹ 3 R⁴ G¹¹ W¹ 4 R⁵ G¹¹ W¹ 5 R⁷ G¹¹ W¹ 6 R⁸ G¹¹ W¹ 7 R¹⁰ G¹¹ W¹ 8 R¹² G¹¹ W¹ 9 R¹⁴ G¹¹ W¹ 10 R¹⁵ G¹¹ W¹ 11 R¹⁹ G¹¹ W¹ 12 R²⁷ G¹¹ W¹ 13 R²⁸ G¹¹ W¹ 14 R³³ G¹¹ W¹ 15 R³⁸ G¹¹ W¹ 16 R³⁹ G¹¹ W¹ 17 R⁴¹ G¹¹ W¹ 18 R⁴⁶ G¹¹ W¹ 19 R⁴⁷ G¹¹ W¹ 20 R⁴⁹ G¹¹ W¹ 21 R¹ G¹² W¹ 22 R² G¹² W¹ 23 R⁴ G¹² W¹ 24 R⁵ G¹² W¹ 25 R⁷ G¹² W¹ 26 R⁸ G¹² W¹ 27 R¹⁰ G¹² W¹ 28 R¹² G¹² W¹ 29 R¹⁴ G¹² W¹ 30 R¹⁵ G¹² W¹ 31 R¹⁹ G¹² W¹ 32 R²⁷ G¹² W¹ 33 R²⁸ G¹² W¹ 34 R³³ G¹² W¹ 35 R³⁸ G¹² W¹ 36 R³⁹ G¹² W¹ 37 R⁴¹ G¹² W¹ 38 R⁴⁶ G¹² W¹ 39 R⁴⁷ G¹² W¹ 40 R⁴⁹ G¹² W¹ 41 R¹ G¹³ W¹ 42 R² G¹³ W¹ 43 R⁴ G¹³ W¹ 44 R⁵ G¹³ W¹ 45 R⁷ G¹³ W¹ 46 R⁸ G¹³ W¹ 47 R¹⁰ G¹³ W¹ 48 R¹² G¹³ W¹ 49 R¹⁴ G¹³ W¹ 50 R¹⁵ G¹³ W¹ 51 R¹⁹ G¹³ W¹ 52 R²⁷ G¹³ W¹ 53 R²⁸ G¹³ W¹ 54 R³³ G¹³ W¹ 55 R³⁸ G¹³ W¹ 56 R³⁹ G¹³ W¹ 57 R⁴¹ G¹³ W¹ 58 R⁴⁶ G¹³ W¹ 59 R⁴⁷ G¹³ W¹ 60 R⁴⁹ G¹³ W¹ 61 R¹ G¹⁶ W¹ 62 R² G¹⁶ W¹ 63 R⁴ G¹⁶ W¹ 64 R⁵ G¹⁶ W¹ 65 R⁷ G¹⁶ W¹ 66 R⁸ G¹⁶ W¹ 67 R¹⁰ G¹⁶ W¹ 68 R¹² G¹⁶ W¹ 69 R¹⁴ G¹⁶ W¹ 70 R¹⁵ G¹⁶ W¹ 71 R¹⁹ G¹⁶ W¹ 72 R²⁷ G¹⁶ W¹ 73 R²⁸ G¹⁶ W¹ 74 R³³ G¹⁶ W¹ 75 R³⁸ G¹⁶ W¹ 76 R³⁹ G¹⁶ W¹ 77 R⁴¹ G¹⁶ W¹ 78 R⁴⁶ G¹⁶ W¹ 79 R⁴⁷ G¹⁶ W¹ 80 R⁴⁹ G¹⁶ W¹ 81 R¹ G¹⁷ W¹ 82 R² G¹⁷ W¹ 83 R⁴ G¹⁷ W¹ 84 R⁵ G¹⁷ W¹ 85 R⁷ G¹⁷ W¹ 86 R⁸ G¹⁷ W¹ 87 R¹⁰ G¹⁷ W¹ 88 R¹² G¹⁷ W¹ 89 R¹⁴ G¹⁷ W¹ 90 R¹⁵ G¹⁷ W¹ 91 R¹⁹ G¹⁷ W¹ 92 R²⁷ G¹⁷ W¹ 93 R²⁸ G¹⁷ W¹ 94 R³³ G¹⁷ W¹ 95 R³⁸ G¹⁷ W¹ 96 R³⁹ G¹⁷ W¹ 97 R⁴¹ G¹⁷ W¹ 98 R⁴⁶ G¹⁷ W¹ 99 R⁴⁷ G¹⁷ W¹ 100 R⁴⁹ G¹⁷ W¹ 101 R¹ G¹⁸ W¹ 102 R² G¹⁸ W¹ 103 R⁴ G¹⁸ W¹ 104 R⁵ G¹⁸ W¹ 105 R⁷ G¹⁸ W¹ 106 R⁸ G¹⁸ W¹ 107 R¹⁰ G¹⁸ W¹ 108 R¹² G¹⁸ W¹ 109 R¹⁴ G¹⁸ W¹ 110 R¹⁵ G¹⁸ W¹ 111 R¹⁹ G¹⁸ W¹ 112 R²⁷ G¹⁸ W¹ 113 R²⁸ G¹⁸ W¹ 114 R³³ G¹⁸ W¹ 115 R³⁸ G¹⁸ W¹ 116 R³⁹ G¹⁸ W¹ 117 R⁴¹ G¹⁸ W¹ 118 R⁴⁶ G¹⁸ W¹ 119 R⁴⁷ G¹⁸ W¹ 120 R⁴⁹ G¹⁸ W¹ 121 R¹ G²¹ W¹ 122 R² G²¹ W¹ 123 R⁴ G²¹ W¹ 124 R⁵ G²¹ W¹ 125 R⁷ G²¹ W¹ 126 R⁸ G²¹ W¹ 127 R¹⁰ G²¹ W¹ 128 R¹² G²¹ W¹ 129 R¹⁴ G²¹ W¹ 130 R¹⁵ G²¹ W¹ 131 R¹⁹ G²¹ W¹ 132 R²⁷ G²¹ W¹ 133 R²⁸ G²¹ W¹ 134 R³³ G²¹ W¹ 135 R³⁸ G²¹ W¹ 136 R³⁹ G²¹ W¹ 137 R⁴¹ G²¹ W¹ 138 R⁴⁶ G²¹ W¹ 139 R⁴⁷ G²¹ W¹ 140 R⁴⁹ G²¹ W¹ 141 R¹ G²² W¹ 142 R² G²² W¹ 143 R⁴ G²² W¹ 144 R⁵ G²² W¹ 145 R⁷ G²² W¹ 146 R⁸ G²² W¹ 147 R¹⁰ G²² W¹ 148 R¹² G²² W¹ 149 R¹⁴ G²² W¹ 150 R¹⁵ G²² W¹ 151 R¹⁹ G²² W¹ 152 R²⁷ G²² W¹ 153 R²⁸ G²² W¹ 154 R³³ G²² W¹ 155 R³⁸ G²² W¹ 156 R³⁹ G²² W¹ 157 R⁴¹ G²² W¹ 158 R⁴⁶ G²² W¹ 159 R⁴⁷ G²² W¹ 160 R⁴⁹ G²² W¹ 161 R¹ G²³ W¹ 162 R² G²³ W¹ 163 R⁴ G²³ W¹ 164 R⁵ G²³ W¹ 165 R⁷ G²³ W¹ 166 R⁸ G²³ W¹ 167 R¹⁰ G²³ W¹ 168 R¹² G²³ W¹ 169 R¹⁴ G²³ W¹ 170 R¹⁵ G²³ W¹ 171 R¹⁹ G²³ W¹ 172 R²⁷ G²³ W¹ 173 R²⁸ G²³ W¹ 174 R³³ G²³ W¹ 175 R³⁸ G²³ W¹ 176 R³⁹ G²³ W¹ 177 R⁴¹ G²³ W¹ 178 R⁴⁶ G²³ W¹ 179 R⁴⁷ G²³ W¹ 180 R⁴⁹ G²³ W¹ 181 R¹ G²⁴ W¹ 182 R² G²⁴ W¹ 183 R⁴ G²⁴ W¹ 184 R⁵ G²⁴ W¹ 185 R⁷ G²⁴ W¹ 186 R⁸ G²⁴ W¹ 187 R¹⁰ G²⁴ W¹ 188 R¹² G²⁴ W¹ 189 R¹⁴ G²⁴ W¹ 190 R¹⁵ G²⁴ W¹ 191 R¹⁹ G²⁴ W¹ 192 R²⁷ G²⁴ W¹ 193 R²⁸ G²⁴ W¹ 194 R³³ G²⁴ W¹ 195 R³⁸ G²⁴ W¹ 196 R³⁹ G²⁴ W¹ 197 R⁴¹ G²⁴ W¹ 198 R⁴⁶ G²⁴ W¹ 199 R⁴⁷ G²⁴ W¹ 200 R⁴⁹ G²⁴ W¹ 201 R¹ G¹¹ W¹¹ 202 R² G¹¹ W¹¹ 203 R⁴ G¹¹ W¹¹ 204 R⁵ G¹¹ W¹¹ 205 R⁷ G¹¹ W¹¹ 206 R⁸ G¹¹ W¹¹ 207 R¹⁰ G¹¹ W¹¹ 208 R¹² G¹¹ W¹¹ 209 R¹⁴ G¹¹ W¹¹ 210 R¹⁵ G¹¹ W¹¹ 211 R¹⁹ G¹¹ W¹¹ 212 R²⁷ G¹¹ W¹¹ 213 R²⁸ G¹¹ W¹¹ 214 R³³ G¹¹ W¹¹ 215 R³⁸ G¹¹ W¹¹ 216 R³⁹ G¹¹ W¹¹ 217 R⁴¹ G¹¹ W¹¹ 218 R⁴⁶ G¹¹ W¹¹ 219 R⁴⁷ G¹¹ W¹¹ 220 R⁴⁹ G¹¹ W¹¹ 221 R¹ G¹² W¹¹ 222 R² G¹² W¹¹ 223 R⁴ G¹² W¹¹ 224 R⁵ G¹² W¹¹ 225 R⁷ G¹² W¹¹ 226 R⁸ G¹² W¹¹ 227 R¹⁰ G¹² W¹¹ 228 R¹² G¹² W¹¹ 229 R¹⁴ G¹² W¹¹ 230 R¹⁵ G¹² W¹¹ 231 R¹⁹ G¹² W¹¹ 232 R²⁷ G¹² W¹¹ 233 R²⁸ G¹² W¹¹ 234 R³³ G¹² W¹¹ 235 R³⁸ G¹² W¹¹ 236 R³⁹ G¹² W¹¹ 237 R⁴¹ G¹² W¹¹ 238 R⁴⁶ G¹² W¹¹ 239 R⁴⁷ G¹² W¹¹ 240 R⁴⁹ G¹² W¹¹ 241 R¹ G¹³ W¹¹ 242 R² G¹³ W¹¹ 243 R⁴ G¹³ W¹¹ 244 R⁵ G¹³ W¹¹ 245 R⁷ G¹³ W¹¹ 246 R⁸ G¹³ W¹¹ 247 R¹⁰ G¹³ W¹¹ 248 R¹² G¹³ W¹¹ 249 R¹⁴ G¹³ W¹¹ 250 R¹⁵ G¹³ W¹¹ 251 R¹⁹ G¹³ W¹¹ 252 R²⁷ G¹³ W¹¹ 253 R²⁸ G¹³ W¹¹ 254 R³³ G¹³ W¹¹ 255 R³⁸ G¹³ W¹¹ 256 R³⁹ G¹³ W¹¹ 257 R⁴¹ G¹³ W¹¹ 258 R⁴⁶ G¹³ W¹¹ 259 R⁴⁷ G¹³ W¹¹ 260 R⁴⁹ G¹³ W¹¹ 261 R¹ G¹⁶ W¹¹ 262 R² G¹⁶ W¹¹ 263 R⁴ G¹⁶ W¹¹ 264 R⁵ G¹⁶ W¹¹ 265 R⁷ G¹⁶ W¹¹ 266 R⁸ G¹⁶ W¹¹ 267 R¹⁰ G¹⁶ W¹¹ 268 R¹² G¹⁶ W¹¹ 269 R¹⁴ G¹⁶ W¹¹ 270 R¹⁵ G¹⁶ W¹¹ 271 R¹⁹ G¹⁶ W¹¹ 272 R²⁷ G¹⁶ W¹¹ 273 R²⁸ G¹⁶ W¹¹ 274 R³³ G¹⁶ W¹¹ 275 R³⁸ G¹⁶ W¹¹ 276 R³⁹ G¹⁶ W¹¹ 277 R⁴¹ G¹⁶ W¹¹ 278 R⁴⁶ G¹⁶ W¹¹ 279 R⁴⁷ G¹⁶ W¹¹ 280 R⁴⁹ G¹⁶ W¹¹ 281 R¹ G¹⁷ W¹¹ 282 R² G¹⁷ W¹¹ 283 R⁴ G¹⁷ W¹¹ 284 R⁵ G¹⁷ W¹¹ 285 R⁷ G¹⁷ W¹¹ 286 R⁸ G¹⁷ W¹¹ 287 R¹⁰ G¹⁷ W¹¹ 288 R¹² G¹⁷ W¹¹ 289 R¹⁴ G¹⁷ W¹¹ 290 R¹⁵ G¹⁷ W¹¹ 291 R¹⁹ G¹⁷ W¹¹ 292 R²⁷ G¹⁷ W¹¹ 293 R²⁸ G¹⁷ W¹¹ 294 R³³ G¹⁷ W¹¹ 295 R³⁸ G¹⁷ W¹¹ 296 R³⁹ G¹⁷ W¹¹ 297 R⁴¹ G¹⁷ W¹¹ 298 R⁴⁶ G¹⁷ W¹¹ 299 R⁴⁷ G¹⁷ W¹¹ 300 R⁴⁹ G¹⁷ W¹¹ 301 R¹ G¹⁸ W¹¹ 302 R² G¹⁸ W¹¹ 303 R⁴ G¹⁸ W¹¹ 304 R⁵ G¹⁸ W¹¹ 305 R⁷ G¹⁸ W¹¹ 306 R⁸ G¹⁸ W¹¹ 307 R¹⁰ G¹⁸ W¹¹ 308 R¹² G¹⁸ W¹¹ 309 R¹⁴ G¹⁸ W¹¹ 310 R¹⁵ G¹⁸ W¹¹ 311 R¹⁹ G¹⁸ W¹¹ 312 R²⁷ G¹⁸ W¹¹ 313 R²⁸ G¹⁸ W¹¹ 314 R³³ G¹⁸ W¹¹ 315 R³⁸ G¹⁸ W¹¹ 316 R³⁹ G¹⁸ W¹¹ 317 R⁴¹ G¹⁸ W¹¹ 318 R⁴⁶ G¹⁸ W¹¹ 319 R⁴⁷ G¹⁸ W¹¹ 320 R⁴⁹ G¹⁸ W¹¹ 321 R¹ G²¹ W¹¹ 322 R² G²¹ W¹¹ 323 R⁴ G²¹ W¹¹ 324 R⁵ G²¹ W¹¹ 325 R⁷ G²¹ W¹¹ 326 R⁸ G²¹ W¹¹ 327 R¹⁰ G²¹ W¹¹ 328 R¹² G²¹ W¹¹ 329 R¹⁴ G²¹ W¹¹ 330 R¹⁵ G²¹ W¹¹ 331 R¹⁹ G²¹ W¹¹ 332 R²⁷ G²¹ W¹¹ 333 R²⁸ G²¹ W¹¹ 334 R³³ G²¹ W¹¹ 335 R³⁸ G²¹ W¹¹ 336 R³⁹ G²¹ W¹¹ 337 R⁴¹ G²¹ W¹¹ 338 R⁴⁶ G²¹ W¹¹ 339 R⁴⁷ G²¹ W¹¹ 340 R⁴⁹ G²¹ W¹¹ 341 R¹ G²² W¹¹ 342 R² G²² W¹¹ 343 R⁴ G²² W¹¹ 344 R⁵ G²² W¹¹ 345 R⁷ G²² W¹¹ 346 R⁸ G²² W¹¹ 347 R¹⁰ G²² W¹¹ 348 R¹² G²² W¹¹ 349 R¹⁴ G²² W¹¹ 350 R¹⁵ G²² W¹¹ 351 R¹⁹ G²² W¹¹ 352 R²⁷ G²² W¹¹ 353 R²⁸ G²² W¹¹ 354 R³³ G²² W¹¹ 355 R³⁸ G²² W¹¹ 356 R³⁹ G²² W¹¹ 357 R⁴¹ G²² W¹¹ 358 R⁴⁶ G²² W¹¹ 359 R⁴⁷ G²² W¹¹ 360 R⁴⁹ G²² W¹¹ 361 R¹ G²³ W¹¹ 362 R² G²³ W¹¹ 363 R⁴ G²³ W¹¹ 364 R⁵ G²³ W¹¹ 365 R⁷ G²³ W¹¹ 366 R⁸ G²³ W¹¹ 367 R¹⁰ G²³ W¹¹ 368 R¹² G²³ W¹¹ 369 R¹⁴ G²³ W¹¹ 370 R¹⁵ G²³ W¹¹ 371 R¹⁹ G²³ W¹¹ 372 R²⁷ G²³ W¹¹ 373 R²⁸ G²³ W¹¹ 374 R³³ G²³ W¹¹ 375 R³⁸ G²³ W¹¹ 376 R³⁹ G²³ W¹¹ 377 R⁴¹ G²³ W¹¹ 378 R⁴⁶ G²³ W¹¹ 379 R⁴⁷ G²³ W¹¹ 380 R⁴⁹ G²³ W¹¹ 381 R¹ G²⁴ W¹¹ 382 R² G²⁴ W¹¹ 383 R⁴ G²⁴ W¹¹ 384 R⁵ G²⁴ W¹¹ 385 R⁷ G²⁴ W¹¹ 386 R⁸ G²⁴ W¹¹ 387 R¹⁰ G²⁴ W¹¹ 388 R¹² G²⁴ W¹¹ 389 R¹⁴ G²⁴ W¹¹ 390 R¹⁵ G²⁴ W¹¹ 391 R¹⁹ G²⁴ W¹¹ 392 R²⁷ G²⁴ W¹¹ 393 R²⁸ G²⁴ W¹¹ 394 R³³ G²⁴ W¹¹ 395 R³⁸ G²⁴ W¹¹ 396 R³⁹ G²⁴ W¹¹ 397 R⁴¹ G²⁴ W¹¹ 398 R⁴⁶ G²⁴ W¹¹ 399 R⁴⁷ G²⁴ W¹¹ 400 R⁴⁹ G²⁴ W¹¹ 401 R¹ G¹¹ W²¹ 402 R² G¹¹ W²¹ 403 R⁴ G¹¹ W²¹ 404 R⁵ G¹¹ W²¹ 405 R⁷ G¹¹ W²¹ 406 R⁸ G¹¹ W²¹ 407 R¹⁰ G¹¹ W²¹ 408 R¹² G¹¹ W²¹ 409 R¹⁴ G¹¹ W²¹ 410 R¹⁵ G¹¹ W²¹ 411 R¹⁹ G¹¹ W²¹ 412 R²⁷ G¹¹ W²¹ 413 R²⁸ G¹¹ W²¹ 414 R³³ G¹¹ W²¹ 415 R³⁸ G¹¹ W²¹ 416 R³⁹ G¹¹ W²¹ 417 R⁴¹ G¹¹ W²¹ 418 R⁴⁶ G¹¹ W²¹ 419 R⁴⁷ G¹¹ W²¹ 420 R⁴⁹ G¹¹ W²¹ 421 R¹ G¹² W²¹ 422 R² G¹² W²¹ 423 R⁴ G¹² W²¹ 424 R⁵ G¹² W²¹ 425 R⁷ G¹² W²¹ 426 R⁸ G¹² W²¹ 427 R¹⁰ G¹² W²¹ 428 R¹² G¹² W²¹ 429 R¹⁴ G¹² W²¹ 430 R¹⁵ G¹² W²¹ 431 R¹⁹ G¹² W²¹ 432 R²⁷ G¹² W²¹ 433 R²⁸ G¹² W²¹ 434 R³³ G¹² W²¹ 435 R³⁸ G¹² W²¹ 436 R³⁹ G¹² W²¹ 437 R⁴¹ G¹² W²¹ 438 R⁴⁶ G¹² W²¹ 439 R⁴⁷ G¹² W²¹ 440 R⁴⁹ G¹² W²¹ 441 R¹ G¹³ W²¹ 442 R² G¹³ W²¹ 443 R⁴ G¹³ W²¹ 444 R⁵ G¹³ W²¹ 445 R⁷ G¹³ W²¹ 446 R⁸ G¹³ W²¹ 447 R¹⁰ G¹³ W²¹ 448 R¹² G¹³ W²¹ 449 R¹⁴ G¹³ W²¹ 450 R¹⁵ G¹³ W²¹ 451 R¹⁹ G¹³ W²¹ 452 R²⁷ G¹³ W²¹ 453 R²⁸ G¹³ W²¹ 454 R³³ G¹³ W²¹ 455 R³⁸ G¹³ W²¹ 456 R³⁹ G¹³ W²¹ 457 R⁴¹ G¹³ W²¹ 458 R⁴⁶ G¹³ W²¹ 459 R⁴⁷ G¹³ W²¹ 460 R⁴⁹ G¹³ W²¹ 461 R¹ G¹⁶ W²¹ 462 R² G¹⁶ W²¹ 463 R⁴ G¹⁶ W²¹ 464 R⁵ G¹⁶ W²¹ 465 R⁷ G¹⁶ W²¹ 466 R⁸ G¹⁶ W²¹ 467 R¹⁰ G¹⁶ W²¹ 468 R¹² G¹⁶ W²¹ 469 R¹⁴ G¹⁶ W²¹ 470 R¹⁵ G¹⁶ W²¹ 471 R¹⁹ G¹⁶ W²¹ 472 R²⁷ G¹⁶ W²¹ 473 R²⁸ G¹⁶ W²¹ 474 R³³ G¹⁶ W²¹ 475 R³⁸ G¹⁶ W²¹ 476 R³⁹ G¹⁶ W²¹ 477 R⁴¹ G¹⁶ W²¹ 478 R⁴⁶ G¹⁶ W²¹ 479 R⁴⁷ G¹⁶ W²¹ 480 R⁴⁹ G¹⁶ W²¹ 481 R¹ G¹⁷ W²¹ 482 R² G¹⁷ W²¹ 483 R⁴ G¹⁷ W²¹ 484 R⁵ G¹⁷ W²¹ 485 R⁷ G¹⁷ W²¹ 486 R⁸ G¹⁷ W²¹ 487 R¹⁰ G¹⁷ W²¹ 488 R¹² G¹⁷ W²¹ 489 R¹⁴ G¹⁷ W²¹ 490 R¹⁵ G¹⁷ W²¹ 491 R¹⁹ G¹⁷ W²¹ 492 R²⁷ G¹⁷ W²¹ 493 R²⁸ G¹⁷ W²¹ 494 R³³ G¹⁷ W²¹ 495 R³⁸ G¹⁷ W²¹ 496 R³⁹ G¹⁷ W²¹ 497 R⁴¹ G¹⁷ W²¹ 498 R⁴⁶ G¹⁷ W²¹ 499 R⁴⁷ G¹⁷ W²¹ 500 R⁴⁹ G¹⁷ W²¹ 501 R¹ G¹⁸ W²¹ 502 R² G¹⁸ W²¹ 503 R⁴ G¹⁸ W²¹ 504 R⁵ G¹⁸ W²¹ 505 R⁷ G¹⁸ W²¹ 506 R⁸ G¹⁸ W²¹ 507 R¹⁰ G¹⁸ W²¹ 508 R¹² G¹⁸ W²¹ 509 R¹⁴ G¹⁸ W²¹ 510 R¹⁵ G¹⁸ W²¹ 511 R¹⁹ G¹⁸ W²¹ 512 R²⁷ G¹⁸ W²¹ 513 R²⁸ G¹⁸ W²¹ 514 R³³ G¹⁸ W²¹ 515 R³⁸ G¹⁸ W²¹ 516 R³⁹ G¹⁸ W²¹ 517 R⁴¹ G¹⁸ W²¹ 518 R⁴⁶ G¹⁸ W²¹ 519 R⁴⁷ G¹⁸ W²¹ 520 R⁴⁹ G¹⁸ W²¹ 521 R¹ G²¹ W²¹ 522 R² G²¹ W²¹ 523 R⁴ G²¹ W²¹ 524 R⁵ G²¹ W²¹ 525 R⁷ G²¹ W²¹ 526 R⁸ G²¹ W²¹ 527 R¹⁰ G²¹ W²¹ 528 R¹² G²¹ W²¹ 529 R¹⁴ G²¹ W²¹ 530 R¹⁵ G²¹ W²¹ 531 R¹⁹ G²¹ W²¹ 532 R²⁷ G²¹ W²¹ 533 R²⁸ G²¹ W²¹ 534 R³³ G²¹ W²¹ 535 R³⁸ G²¹ W²¹ 536 R³⁹ G²¹ W²¹ 537 R⁴¹ G²¹ W²¹ 538 R⁴⁶ G²¹ W²¹ 539 R⁴⁷ G²¹ W²¹ 540 R⁴⁹ G²¹ W²¹ 541 R¹ G²² W²¹ 542 R² G²² W²¹ 543 R⁴ G²² W²¹ 544 R⁵ G²² W²¹ 545 R⁷ G²² W²¹ 546 R⁸ G²² W²¹ 547 R¹⁰ G²² W²¹ 548 R¹² G²² W²¹ 549 R¹⁴ G²² W²¹ 550 R¹⁵ G²² W²¹ 551 R¹⁹ G²² W²¹ 552 R²⁷ G²² W²¹ 553 R²⁸ G²² W²¹ 554 R³³ G²² W²¹ 555 R³⁸ G²² W²¹ 556 R³⁹ G²² W²¹ 557 R⁴¹ G²² W²¹ 558 R⁴⁶ G²² W²¹ 559 R⁴⁷ G²² W²¹ 560 R⁴⁹ G²² W²¹ 561 R¹ G²³ W²¹ 562 R² G²³ W²¹ 563 R⁴ G²³ W²¹ 564 R⁵ G²³ W²¹ 565 R⁷ G²³ W²¹ 566 R⁸ G²³ W²¹ 567 R¹⁰ G²³ W²¹ 568 R¹² G²³ W²¹ 569 R¹⁴ G²³ W²¹ 570 R¹⁵ G²³ W²¹ 571 R¹⁹ G²³ W²¹ 572 R²⁷ G²³ W²¹ 573 R²⁸ G²³ W²¹ 574 R³³ G²³ W²¹ 575 R³⁸ G²³ W²¹ 576 R³⁹ G²³ W²¹ 577 R⁴¹ G²³ W²¹ 578 R⁴⁶ G²³ W²¹ 579 R⁴⁷ G²³ W²¹ 580 R⁴⁹ G²³ W²¹ 581 R¹ G²⁴ W²¹ 582 R² G²⁴ W²¹ 583 R⁴ G²⁴ W²¹ 584 R⁵ G²⁴ W²¹ 585 R⁷ G²⁴ W²¹ 586 R⁸ G²⁴ W²¹ 587 R¹⁰ G²⁴ W²¹ 588 R¹² G²⁴ W²¹ 589 R¹⁴ G²⁴ W²¹ 590 R¹⁵ G²⁴ W²¹ 591 R¹⁹ G²⁴ W²¹ 592 R²⁷ G²⁴ W²¹ 593 R²⁸ G²⁴ W²¹ 594 R³³ G²⁴ W²¹ 595 R³⁸ G²⁴ W²¹ 596 R³⁹ G²⁴ W²¹ 597 R⁴¹ G²⁴ W²¹ 598 R⁴⁶ G²⁴ W²¹ 599 R⁴⁷ G²⁴ W²¹ 600 R⁴⁹ G²⁴ W²¹ 601 R¹ G¹¹ W²⁸ 602 R² G¹¹ W²⁸ 603 R⁴ G¹¹ W²⁸ 604 R⁵ G¹¹ W²⁸ 605 R⁷ G¹¹ W²⁸ 606 R⁸ G¹¹ W²⁸ 607 R¹⁰ G¹¹ W²⁸ 608 R¹² G¹¹ W²⁸ 609 R¹⁴ G¹¹ W²⁸ 610 R¹⁵ G¹¹ W²⁸ 611 R¹⁹ G¹¹ W²⁸ 612 R²⁷ G¹¹ W²⁸ 613 R²⁸ G¹¹ W²⁸ 614 R³³ G¹¹ W²⁸ 615 R³⁸ G¹¹ W²⁸ 616 R³⁹ G¹¹ W²⁸ 617 R⁴¹ G¹¹ W²⁸ 618 R⁴⁶ G¹¹ W²⁸ 619 R⁴⁷ G¹¹ W²⁸ 620 R⁴⁹ G¹¹ W²⁸ 621 R¹ G¹² W²⁸ 622 R² G¹² W²⁸ 623 R⁴ G¹² W²⁸ 624 R⁵ G¹² W²⁸ 625 R⁷ G¹² W²⁸ 626 R⁸ G¹² W²⁸ 627 R¹⁰ G¹² W²⁸ 628 R¹² G¹² W²⁸ 629 R¹⁴ G¹² W²⁸ 630 R¹⁵ G¹² W²⁸ 631 R¹⁹ G¹² W²⁸ 632 R²⁷ G¹² W²⁸ 633 R²⁸ G¹² W²⁸ 634 R³³ G¹² W²⁸ 635 R³⁸ G¹² W²⁸ 636 R³⁹ G¹² W²⁸ 637 R⁴¹ G¹² W²⁸ 638 R⁴⁶ G¹² W²⁸ 639 R⁴⁷ G¹² W²⁸ 640 R⁴⁹ G¹² W²⁸ 641 R¹ G¹³ W²⁸ 642 R² G¹³ W²⁸ 643 R⁴ G¹³ W²⁸ 644 R⁵ G¹³ W²⁸ 645 R⁷ G¹³ W²⁸ 646 R⁸ G¹³ W²⁸ 647 R¹⁰ G¹³ W²⁸ 648 R¹² G¹³ W²⁸ 649 R¹⁴ G¹³ W²⁸ 650 R¹⁵ G¹³ W²⁸ 651 R¹⁹ G¹³ W²⁸ 652 R²⁷ G¹³ W²⁸ 653 R²⁸ G¹³ W²⁸ 654 R³³ G¹³ W²⁸ 655 R³⁸ G¹³ W²⁸ 656 R³⁹ G¹³ W²⁸ 657 R⁴¹ G¹³ W²⁸ 658 R⁴⁶ G¹³ W²⁸ 659 R⁴⁷ G¹³ W²⁸ 660 R⁴⁹ G¹³ W²⁸ 661 R¹ G¹⁴ W²⁸ 662 R² G¹⁴ W²⁸ 663 R⁴ G¹⁴ W²⁸ 664 R⁵ G¹⁴ W²⁸ 665 R⁷ G¹⁴ W²⁸ 666 R⁸ G¹⁴ W²⁸ 667 R¹⁰ G¹⁴ W²⁸ 668 R¹² G¹⁴ W²⁸ 669 R¹⁴ G¹⁴ W²⁸ 670 R¹⁵ G¹⁴ W²⁸ 671 R¹⁹ G¹⁴ W²⁸ 672 R²⁷ G¹⁴ W²⁸ 673 R²⁸ G¹⁴ W²⁸ 674 R³³ G¹⁴ W²⁸ 675 R³⁸ G¹⁴ W²⁸ 676 R³⁹ G¹⁴ W²⁸ 677 R⁴¹ G¹⁴ W²⁸ 678 R⁴⁶ G¹⁴ W²⁸ 679 R⁴⁷ G¹⁴ W²⁸ 680 R⁴⁹ G¹⁴ W²⁸ 681 R¹ G¹⁵ W²⁸ 682 R² G¹⁵ W²⁸ 683 R⁴ G¹⁵ W²⁸ 684 R⁵ G¹⁵ W²⁸ 685 R⁷ G¹⁵ W²⁸ 686 R⁸ G¹⁵ W²⁸ 687 R¹⁰ G¹⁵ W²⁸ 688 R¹² G¹⁵ W²⁸ 689 R¹⁴ G¹⁵ W²⁸ 690 R¹⁵ G¹⁵ W²⁸ 691 R¹⁹ G¹⁵ W²⁸ 692 R²⁷ G¹⁵ W²⁸ 693 R²⁸ G¹⁵ W²⁸ 694 R³³ G¹⁵ W²⁸ 695 R³⁸ G¹⁵ W²⁸ 696 R³⁹ G¹⁵ W²⁸ 697 R⁴¹ G¹⁵ W²⁸ 698 R⁴⁶ G¹⁵ W²⁸ 699 R⁴⁷ G¹⁵ W²⁸ 700 R⁴⁹ G¹⁵ W²⁸ 701 R¹ G¹⁶ W²⁸ 702 R² G¹⁶ W²⁸ 703 R⁴ G¹⁶ W²⁸ 704 R⁵ G¹⁶ W²⁸ 705 R⁷ G¹⁶ W²⁸ 706 R⁸ G¹⁶ W²⁸ 707 R¹⁰ G¹⁶ W²⁸ 708 R¹² G¹⁶ W²⁸ 709 R¹⁴ G¹⁶ W²⁸ 710 R¹⁵ G¹⁶ W²⁸ 711 R¹⁹ G¹⁶ W²⁸ 712 R²⁷ G¹⁶ W²⁸ 713 R²⁸ G¹⁶ W²⁸ 714 R³³ G¹⁶ W²⁸ 715 R³⁸ G¹⁶ W²⁸ 716 R³⁹ G¹⁶ W²⁸ 717 R⁴¹ G¹⁶ W²⁸ 718 R⁴⁶ G¹⁶ W²⁸ 719 R⁴⁷ G¹⁶ W²⁸ 720 R⁴⁹ G¹⁶ W²⁸ 721 R¹ G¹⁷ W²⁸ 722 R² G¹⁷ W²⁸ 723 R⁴ G¹⁷ W²⁸ 724 R⁵ G¹⁷ W²⁸ 725 R⁷ G¹⁷ W²⁸ 726 R⁸ G¹⁷ W²⁸ 727 R¹⁰ G¹⁷ W²⁸ 728 R¹² G¹⁷ W²⁸ 729 R¹⁴ G¹⁷ W²⁸ 730 R¹⁵ G¹⁷ W²⁸ 731 R¹⁹ G¹⁷ W²⁸ 732 R²⁷ G¹⁷ W²⁸ 733 R²⁸ G¹⁷ W²⁸ 734 R³³ G¹⁷ W²⁸ 735 R³⁸ G¹⁷ W²⁸ 736 R³⁹ G¹⁷ W²⁸ 737 R⁴¹ G¹⁷ W²⁸ 738 R⁴⁶ G¹⁷ W²⁸ 739 R⁴⁷ G¹⁷ W²⁸ 740 R⁴⁹ G¹⁷ W²⁸ 741 R¹ G¹⁸ W²⁸ 742 R² G¹⁸ W²⁸ 743 R⁴ G¹⁸ W²⁸ 744 R⁵ G¹⁸ W²⁸ 745 R⁷ G¹⁸ W²⁸ 746 R⁸ G¹⁸ W²⁸ 747 R¹⁰ G¹⁸ W²⁸ 748 R¹² G¹⁸ W²⁸ 749 R¹⁴ G¹⁸ W²⁸ 750 R¹⁵ G¹⁸ W²⁸ 751 R¹⁹ G¹⁸ W²⁸ 752 R²⁷ G¹⁸ W²⁸ 753 R²⁸ G¹⁸ W²⁸ 754 R³³ G¹⁸ W²⁸ 755 R³⁸ G¹⁸ W²⁸ 756 R³⁹ G¹⁸ W²⁸ 757 R⁴¹ G¹⁸ W²⁸ 758 R⁴⁶ G¹⁸ W²⁸ 759 R⁴⁷ G¹⁸ W²⁸ 760 R⁴⁹ G¹⁸ W²⁸ 761 R¹ G¹⁹ W²⁸ 762 R² G¹⁹ W²⁸ 763 R⁴ G¹⁹ W²⁸ 764 R⁵ G¹⁹ W²⁸ 765 R⁷ G¹⁹ W²⁸ 766 R⁸ G¹⁹ W²⁸ 767 R¹⁰ G¹⁹ W²⁸ 768 R¹² G¹⁹ W²⁸ 769 R¹⁴ G¹⁹ W²⁸ 770 R¹⁵ G¹⁹ W²⁸ 771 R¹⁹ G¹⁹ W²⁸ 772 R²⁷ G¹⁹ W²⁸ 773 R²⁸ G¹⁹ W²⁸ 774 R³³ G¹⁹ W²⁸ 775 R³⁸ G¹⁹ W²⁸ 776 R³⁹ G¹⁹ W²⁸ 777 R⁴¹ G¹⁹ W²⁸ 778 R⁴⁶ G¹⁹ W²⁸ 779 R⁴⁷ G¹⁹ W²⁸ 780 R⁴⁹ G¹⁹ W²⁸ 781 R¹ G²⁰ W²⁸ 782 R² G²⁰ W²⁸ 783 R⁴ G²⁰ W²⁸ 784 R⁵ G²⁰ W²⁸ 785 R⁷ G²⁰ W²⁸ 786 R⁸ G²⁰ W²⁸ 787 R¹⁰ G²⁰ W²⁸ 788 R¹² G²⁰ W²⁸ 789 R¹⁴ G²⁰ W²⁸ 790 R¹⁵ G²⁰ W²⁸ 791 R¹⁹ G²⁰ W²⁸ 792 R²⁷ G²⁰ W²⁸ 793 R²⁸ G²⁰ W²⁸ 794 R³³ G²⁰ W²⁸ 795 R³⁸ G²⁰ W²⁸ 796 R³⁹ G²⁰ W²⁸ 797 R⁴¹ G²⁰ W²⁸ 798 R⁴⁶ G²⁰ W²⁸ 799 R⁴⁷ G²⁰ W²⁸ 800 R⁴⁹ G²⁰ W²⁸ 801 R¹ G¹¹ W³⁶ 802 R² G¹¹ W³⁶ 803 R⁴ G¹¹ W³⁶ 804 R⁵ G¹¹ W³⁶ 805 R⁷ G¹¹ W³⁶ 806 R⁸ G¹¹ W³⁶ 807 R¹⁰ G¹¹ W³⁶ 808 R¹² G¹¹ W³⁶ 809 R¹⁴ G¹¹ W³⁶ 810 R¹⁵ G¹¹ W³⁶ 811 R¹⁹ G¹¹ W³⁶ 812 R²⁷ G¹¹ W³⁶ 813 R²⁸ G¹¹ W³⁶ 814 R³³ G¹¹ W³⁶ 815 R³⁸ G¹¹ W³⁶ 816 R³⁹ G¹¹ W³⁶ 817 R⁴¹ G¹¹ W³⁶ 818 R⁴⁶ G¹¹ W³⁶ 819 R⁴⁷ G¹¹ W³⁶ 820 R⁴⁹ G¹¹ W³⁶ 821 R¹ G¹² W³⁶ 822 R² G¹² W³⁶ 823 R⁴ G¹² W³⁶ 824 R⁵ G¹² W³⁶ 825 R⁷ G¹² W³⁶ 826 R⁸ G¹² W³⁶ 827 R¹⁰ G¹² W³⁶ 828 R¹² G¹² W³⁶ 829 R¹⁴ G¹² W³⁶ 830 R¹⁵ G¹² W³⁶ 831 R¹⁹ G¹² W³⁶ 832 R²⁷ G¹² W³⁶ 833 R²⁸ G¹² W³⁶ 834 R³³ G¹² W³⁶ 835 R³⁸ G¹² W³⁶ 836 R³⁹ G¹² W³⁶ 837 R⁴¹ G¹² W³⁶ 838 R⁴⁶ G¹² W³⁶ 839 R⁴⁷ G¹² W³⁶ 840 R⁴⁹ G¹² W³⁶ 841 R¹ G¹³ W³⁶ 842 R² G¹³ W³⁶ 843 R⁴ G¹³ W³⁶ 844 R⁵ G¹³ W³⁶ 845 R⁷ G¹³ W³⁶ 846 R⁸ G¹³ W³⁶ 847 R¹⁰ G¹³ W³⁶ 848 R¹² G¹³ W³⁶ 849 R¹⁴ G¹³ W³⁶ 850 R¹⁵ G¹³ W³⁶ 851 R¹⁹ G¹³ W³⁶ 852 R²⁷ G¹³ W³⁶ 853 R²⁸ G¹³ W³⁶ 854 R³³ G¹³ W³⁶ 855 R³⁸ G¹³ W³⁶ 856 R³⁹ G¹³ W³⁶ 857 R⁴¹ G¹³ W³⁶ 858 R⁴⁶ G¹³ W³⁶ 859 R⁴⁷ G¹³ W³⁶ 860 R⁴⁹ G¹³ W³⁶ 861 R¹ G¹⁴ W³⁶ 862 R² G¹⁴ W³⁶ 863 R⁴ G¹⁴ W³⁶ 864 R⁵ G¹⁴ W³⁶ 865 R⁷ G¹⁴ W³⁶ 866 R⁸ G¹⁴ W³⁶ 867 R¹⁰ G¹⁴ W³⁶ 868 R¹² G¹⁴ W³⁶ 869 R¹⁴ G¹⁴ W³⁶ 870 R¹⁵ G¹⁴ W³⁶ 871 R¹⁹ G¹⁴ W³⁶ 872 R²⁷ G¹⁴ W³⁶ 873 R²⁸ G¹⁴ W³⁶ 874 R³³ G¹⁴ W³⁶ 875 R³⁸ G¹⁴ W³⁶ 876 R³⁹ G¹⁴ W³⁶ 877 R⁴¹ G¹⁴ W³⁶ 878 R⁴⁶ G¹⁴ W³⁶ 879 R⁴⁷ G¹⁴ W³⁶ 880 R⁴⁹ G¹⁴ W³⁶ 881 R¹ G¹⁵ W³⁶ 882 R² G¹⁵ W³⁶ 883 R⁴ G¹⁵ W³⁶ 884 R⁵ G¹⁵ W³⁶ 885 R⁷ G¹⁵ W³⁶ 886 R⁸ G¹⁵ W³⁶ 887 R¹⁰ G¹⁵ W³⁶ 888 R¹² G¹⁵ W³⁶ 889 R¹⁴ G¹⁵ W³⁶ 890 R¹⁵ G¹⁵ W³⁶ 891 R¹⁹ G¹⁵ W³⁶ 892 R²⁷ G¹⁵ W³⁶ 893 R²⁸ G¹⁵ W³⁶ 894 R³³ G¹⁵ W³⁶ 895 R³⁸ G¹⁵ W³⁶ 896 R³⁹ G¹⁵ W³⁶ 897 R⁴¹ G¹⁵ W³⁶ 898 R⁴⁶ G¹⁵ W³⁶ 899 R⁴⁷ G¹⁵ W³⁶ 900 R⁴⁹ G¹⁵ W³⁶ 901 R¹ G¹⁶ W³⁶ 902 R² G¹⁶ W³⁶ 903 R⁴ G¹⁶ W³⁶ 904 R⁵ G¹⁶ W³⁶ 905 R⁷ G¹⁶ W³⁶ 906 R⁸ G¹⁶ W³⁶ 907 R¹⁰ G¹⁶ W³⁶ 908 R¹² G¹⁶ W³⁶ 909 R¹⁴ G¹⁶ W³⁶ 910 R¹⁵ G¹⁶ W³⁶ 911 R¹⁹ G¹⁶ W³⁶ 912 R²⁷ G¹⁶ W³⁶ 913 R²⁸ G¹⁶ W³⁶ 914 R³³ G¹⁶ W³⁶ 915 R³⁸ G¹⁶ W³⁶ 916 R³⁹ G¹⁶ W³⁶ 917 R⁴¹ G¹⁶ W³⁶ 918 R⁴⁶ G¹⁶ W³⁶ 919 R⁴⁷ G¹⁶ W³⁶ 920 R⁴⁹ G¹⁶ W³⁶ 921 R¹ G¹⁷ W³⁶ 922 R² G¹⁷ W³⁶ 923 R⁴ G¹⁷ W³⁶ 924 R⁵ G¹⁷ W³⁶ 925 R⁷ G¹⁷ W³⁶ 926 R⁸ G¹⁷ W³⁶ 927 R¹⁰ G¹⁷ W³⁶ 928 R¹² G¹⁷ W³⁶ 929 R¹⁴ G¹⁷ W³⁶ 930 R¹⁵ G¹⁷ W³⁶ 931 R¹⁹ G¹⁷ W³⁶ 932 R²⁷ G¹⁷ W³⁶ 933 R²⁸ G¹⁷ W³⁶ 934 R³³ G¹⁷ W³⁶ 935 R³⁸ G¹⁷ W³⁶ 936 R³⁹ G¹⁷ W³⁶ 937 R⁴¹ G¹⁷ W³⁶ 938 R⁴⁶ G¹⁷ W³⁶ 939 R⁴⁷ G¹⁷ W³⁶ 940 R⁴⁹ G¹⁷ W³⁶ 941 R¹ G¹⁸ W³⁶ 942 R² G¹⁸ W³⁶ 943 R⁴ G¹⁸ W³⁶ 944 R⁵ G¹⁸ W³⁶ 945 R⁷ G¹⁸ W³⁶ 946 R⁸ G¹⁸ W³⁶ 947 R¹⁰ G¹⁸ W³⁶ 948 R¹² G¹⁸ W³⁶ 949 R¹⁴ G¹⁸ W³⁶ 950 R¹⁵ G¹⁸ W³⁶ 951 R¹⁹ G¹⁸ W³⁶ 952 R²⁷ G¹⁸ W³⁶ 953 R²⁸ G¹⁸ W³⁶ 954 R³³ G¹⁸ W³⁶ 955 R³⁸ G¹⁸ W³⁶ 956 R³⁹ G¹⁸ W³⁶ 957 R⁴¹ G¹⁸ W³⁶ 958 R⁴⁶ G¹⁸ W³⁶ 959 R⁴⁷ G¹⁸ W³⁶ 960 R⁴⁹ G¹⁸ W³⁶ 961 R¹ G¹⁹ W³⁶ 962 R² G¹⁹ W³⁶ 963 R⁴ G¹⁹ W³⁶ 964 R⁵ G¹⁹ W³⁶ 965 R⁷ G¹⁹ W³⁶ 966 R⁸ G¹⁹ W³⁶ 967 R¹⁰ G¹⁹ W³⁶ 968 R¹² G¹⁹ W³⁶ 969 R¹⁴ G¹⁹ W³⁶ 970 R¹⁵ G¹⁹ W³⁶ 971 R¹⁹ G¹⁹ W³⁶ 972 R²⁷ G¹⁹ W³⁶ 973 R²⁸ G¹⁹ W³⁶ 974 R³³ G¹⁹ W³⁶ 975 R³⁸ G¹⁹ W³⁶ 976 R³⁹ G¹⁹ W³⁶ 977 R⁴¹ G¹⁹ W³⁶ 978 R⁴⁶ G¹⁹ W³⁶ 979 R⁴⁷ G¹⁹ W³⁶ 980 R⁴⁹ G¹⁹ W³⁶ 981 R¹ G²⁰ W³⁶ 982 R² G²⁰ W³⁶ 983 R⁴ G²⁰ W³⁶ 984 R⁵ G²⁰ W³⁶ 985 R⁷ G²⁰ W³⁶ 986 R⁸ G²⁰ W³⁶ 987 R¹⁰ G²⁰ W³⁶ 988 R¹² G²⁰ W³⁶ 989 R¹⁴ G²⁰ W³⁶ 990 R¹⁵ G²⁰ W³⁶ 991 R¹⁹ G²⁰ W³⁶ 992 R²⁷ G²⁰ W³⁶ 993 R²⁸ G²⁰ W³⁶ 994 R³³ G²⁰ W³⁶ 995 R³⁸ G²⁰ W³⁶ 996 R³⁹ G²⁰ W³⁶ 997 R⁴¹ G²⁰ W³⁶ 998 R⁴⁶ G²⁰ W³⁶ 999 R⁴⁷ G²⁰ W³⁶ 1000 R⁴⁹ G²⁰ W³⁶ 1001 R¹ G¹¹ W³⁷ 1002 R² G¹¹ W³⁷ 1003 R⁴ G¹¹ W³⁷ 1004 R⁵ G¹¹ W³⁷ 1005 R⁷ G¹¹ W³⁷ 1006 R⁸ G¹¹ W³⁷ 1007 R¹⁰ G¹¹ W³⁷ 1008 R¹² G¹¹ W³⁷ 1009 R¹⁴ G¹¹ W³⁷ 1010 R¹⁵ G¹¹ W³⁷ 1011 R¹⁹ G¹¹ W³⁷ 1012 R²⁷ G¹¹ W³⁷ 1013 R²⁸ G¹¹ W³⁷ 1014 R³³ G¹¹ W³⁷ 1015 R³⁸ G¹¹ W³⁷ 1016 R³⁹ G¹¹ W³⁷ 1017 R⁴¹ G¹¹ W³⁷ 1018 R⁴⁶ G¹¹ W³⁷ 1019 R⁴⁷ G¹¹ W³⁷ 1020 R⁴⁹ G¹¹ W³⁷ 1021 R¹ G¹² W³⁷ 1022 R² G¹² W³⁷ 1023 R⁴ G¹² W³⁷ 1024 R⁵ G¹² W³⁷ 1025 R⁷ G¹² W³⁷ 1026 R⁸ G¹² W³⁷ 1027 R¹⁰ G¹² W³⁷ 1028 R¹² G¹² W³⁷ 1029 R¹⁴ G¹² W³⁷ 1030 R¹⁵ G¹² W³⁷ 1031 R¹⁹ G¹² W³⁷ 1032 R²⁷ G¹² W³⁷ 1033 R²⁸ G¹² W³⁷ 1034 R³³ G¹² W³⁷ 1035 R³⁸ G¹² W³⁷ 1036 R³⁹ G¹² W³⁷ 1037 R⁴¹ G¹² W³⁷ 1038 R⁴⁶ G¹² W³⁷ 1039 R⁴⁷ G¹² W³⁷ 1040 R⁴⁹ G¹² W³⁷ 1041 R¹ G¹³ W³⁷ 1042 R² G¹³ W³⁷ 1043 R⁴ G¹³ W³⁷ 1044 R⁵ G¹³ W³⁷ 1045 R⁷ G¹³ W³⁷ 1046 R⁸ G¹³ W³⁷ 1047 R¹⁰ G¹³ W³⁷ 1048 R¹² G¹³ W³⁷ 1049 R¹⁴ G¹³ W³⁷ 1050 R¹⁵ G¹³ W³⁷ 1051 R¹⁹ G¹³ W³⁷ 1052 R²⁷ G¹³ W³⁷ 1053 R²⁸ G¹³ W³⁷ 1054 R³³ G¹³ W³⁷ 1055 R³⁸ G¹³ W³⁷ 1056 R³⁹ G¹³ W³⁷ 1057 R⁴¹ G¹³ W³⁷ 1058 R⁴⁶ G¹³ W³⁷ 1059 R⁴⁷ G¹³ W³⁷ 1060 R⁴⁹ G¹³ W³⁷ 1061 R¹ G¹⁴ W³⁷ 1062 R² G¹⁴ W³⁷ 1063 R⁴ G¹⁴ W³⁷ 1064 R⁵ G¹⁴ W³⁷ 1065 R⁷ G¹⁴ W³⁷ 1066 R⁸ G¹⁴ W³⁷ 1067 R¹⁰ G¹⁴ W³⁷ 1068 R¹² G¹⁴ W³⁷ 1069 R¹⁴ G¹⁴ W³⁷ 1070 R¹⁵ G¹⁴ W³⁷ 1071 R¹⁹ G¹⁴ W³⁷ 1072 R²⁷ G¹⁴ W³⁷ 1073 R²⁸ G¹⁴ W³⁷ 1074 R³³ G¹⁴ W³⁷ 1075 R³⁸ G¹⁴ W³⁷ 1076 R³⁹ G¹⁴ W³⁷ 1077 R⁴¹ G¹⁴ W³⁷ 1078 R⁴⁶ G¹⁴ W³⁷ 1079 R⁴⁷ G¹⁴ W³⁷ 1080 R⁴⁹ G¹⁴ W³⁷ 1081 R¹ G¹⁵ W³⁷ 1082 R² G¹⁵ W³⁷ 1083 R⁴ G¹⁵ W³⁷ 1084 R⁵ G¹⁵ W³⁷ 1085 R⁷ G¹⁵ W³⁷ 1086 R⁸ G¹⁵ W³⁷ 1087 R¹⁰ G¹⁵ W³⁷ 1088 R¹² G¹⁵ W³⁷ 1089 R¹⁴ G¹⁵ W³⁷ 1090 R¹⁵ G¹⁵ W³⁷ 1091 R¹⁹ G¹⁵ W³⁷ 1092 R²⁷ G¹⁵ W³⁷ 1093 R²⁸ G¹⁵ W³⁷ 1094 R³³ G¹⁵ W³⁷ 1095 R³⁸ G¹⁵ W³⁷ 1096 R³⁹ G¹⁵ W³⁷ 1097 R⁴¹ G¹⁵ W³⁷ 1098 R⁴⁶ G¹⁵ W³⁷ 1099 R⁴⁷ G¹⁵ W³⁷ 1100 R⁴⁹ G¹⁵ W³⁷ 1101 R¹ G¹⁶ W³⁷ 1102 R² G¹⁶ W³⁷ 1103 R⁴ G¹⁶ W³⁷ 1104 R⁵ G¹⁶ W³⁷ 1105 R⁷ G¹⁶ W³⁷ 1106 R⁸ G¹⁶ W³⁷ 1107 R¹⁰ G¹⁶ W³⁷ 1108 R¹² G¹⁶ W³⁷ 1109 R¹⁴ G¹⁶ W³⁷ 1110 R¹⁵ G¹⁶ W³⁷ 1111 R¹⁹ G¹⁶ W³⁷ 1112 R²⁷ G¹⁶ W³⁷ 1113 R²⁸ G¹⁶ W³⁷ 1114 R³³ G¹⁶ W³⁷ 1115 R³⁸ G¹⁶ W³⁷ 1116 R³⁹ G¹⁶ W³⁷ 1117 R⁴¹ G¹⁶ W³⁷ 1118 R⁴⁶ G¹⁶ W³⁷ 1119 R⁴⁷ G¹⁶ W³⁷ 1120 R⁴⁹ G¹⁶ W³⁷ 1121 R¹ G¹⁷ W³⁷ 1122 R² G¹⁷ W³⁷ 1123 R⁴ G¹⁷ W³⁷ 1124 R⁵ G¹⁷ W³⁷ 1125 R⁷ G¹⁷ W³⁷ 1126 R⁸ G¹⁷ W³⁷ 1127 R¹⁰ G¹⁷ W³⁷ 1128 R¹² G¹⁷ W³⁷ 1129 R¹⁴ G¹⁷ W³⁷ 1130 R¹⁵ G¹⁷ W³⁷ 1131 R¹⁹ G¹⁷ W³⁷ 1132 R²⁷ G¹⁷ W³⁷ 1133 R²⁸ G¹⁷ W³⁷ 1134 R³³ G¹⁷ W³⁷ 1135 R³⁸ G¹⁷ W³⁷ 1136 R³⁹ G¹⁷ W³⁷ 1137 R⁴¹ G¹⁷ W³⁷ 1138 R⁴⁶ G¹⁷ W³⁷ 1139 R⁴⁷ G¹⁷ W³⁷ 1140 R⁴⁹ G¹⁷ W³⁷ 1141 R¹ G¹⁸ W³⁷ 1142 R² G¹⁸ W³⁷ 1143 R⁴ G¹⁸ W³⁷ 1144 R⁵ G¹⁸ W³⁷ 1145 R⁷ G¹⁸ W³⁷ 1146 R⁸ G¹⁸ W³⁷ 1147 R¹⁰ G¹⁸ W³⁷ 1148 R¹² G¹⁸ W³⁷ 1149 R¹⁴ G¹⁸ W³⁷ 1150 R¹⁵ G¹⁸ W³⁷ 1151 R¹⁹ G¹⁸ W³⁷ 1152 R²⁷ G¹⁸ W³⁷ 1153 R²⁸ G¹⁸ W³⁷ 1154 R³³ G¹⁸ W³⁷ 1155 R³⁸ G¹⁸ W³⁷ 1156 R³⁹ G¹⁸ W³⁷ 1157 R⁴¹ G¹⁸ W³⁷ 1158 R⁴⁶ G¹⁸ W³⁷ 1159 R⁴⁷ G¹⁸ W³⁷ 1160 R⁴⁹ G¹⁸ W³⁷ 1161 R¹ G¹⁹ W³⁷ 1162 R² G¹⁹ W³⁷ 1163 R⁴ G¹⁹ W³⁷ 1164 R⁵ G¹⁹ W³⁷ 1165 R⁷ G¹⁹ W³⁷ 1166 R⁸ G¹⁹ W³⁷ 1167 R¹⁰ G¹⁹ W³⁷ 1168 R¹² G¹⁹ W³⁷ 1169 R¹⁴ G¹⁹ W³⁷ 1170 R¹⁵ G¹⁹ W³⁷ 1171 R¹⁹ G¹⁹ W³⁷ 1172 R²⁷ G¹⁹ W³⁷ 1173 R²⁸ G¹⁹ W³⁷ 1174 R³³ G¹⁹ W³⁷ 1175 R³⁸ G¹⁹ W³⁷ 1176 R³⁹ G¹⁹ W³⁷ 1177 R⁴¹ G¹⁹ W³⁷ 1178 R⁴⁶ G¹⁹ W³⁷ 1179 R⁴⁷ G¹⁹ W³⁷ 1180 R⁴⁹ G¹⁹ W³⁷ 1181 R¹ G²⁰ W³⁷ 1182 R² G²⁰ W³⁷ 1183 R⁴ G²⁰ W³⁷ 1184 R⁵ G²⁰ W³⁷ 1185 R⁷ G²⁰ W³⁷ 1186 R⁸ G²⁰ W³⁷ 1187 R¹⁰ G²⁰ W³⁷ 1188 R¹² G²⁰ W³⁷ 1189 R¹⁴ G²⁰ W³⁷ 1190 R¹⁵ G²⁰ W³⁷ 1191 R¹⁹ G²⁰ W³⁷ 1192 R²⁷ G²⁰ W³⁷ 1193 R²⁸ G²⁰ W³⁷ 1194 R³³ G²⁰ W³⁷ 1195 R³⁸ G²⁰ W³⁷ 1196 R³⁹ G²⁰ W³⁷ 1197 R⁴¹ G²⁰ W³⁷ 1198 R⁴⁶ G²⁰ W³⁷ 1199 R⁴⁷ G²⁰ W³⁷ 1200 R⁴⁹ G²⁰ W³⁷ 1201 R¹ G²⁹ W⁴² 1202 R² G²⁹ W⁴² 1203 R⁴ G²⁹ W⁴² 1204 R⁵ G²⁹ W⁴² 1205 R⁷ G²⁹ W⁴² 1206 R⁸ G²⁹ W⁴² 1207 R¹⁰ G²⁹ W⁴² 1208 R¹² G²⁹ W⁴² 1209 R¹⁴ G²⁹ W⁴² 1210 R¹⁵ G²⁹ W⁴² 1211 R¹⁹ G²⁹ W⁴² 1212 R²⁷ G²⁹ W⁴² 1213 R²⁸ G²⁹ W⁴² 1214 R³³ G²⁹ W⁴² 1215 R³⁸ G²⁹ W⁴² 1216 R³⁹ G²⁹ W⁴² 1217 R⁴¹ G²⁹ W⁴² 1218 R⁴⁶ G²⁹ W⁴² 1219 R⁴⁷ G²⁹ W⁴² 1220 R⁴⁹ G²⁹ W⁴² 1221 R¹ G³⁰ W⁴² 1222 R² G³⁰ W⁴² 1223 R⁴ G³⁰ W⁴² 1224 R⁵ G³⁰ W⁴² 1225 R⁷ G³⁰ W⁴² 1226 R⁸ G³⁰ W⁴² 1227 R¹⁰ G³⁰ W⁴² 1228 R¹² G³⁰ W⁴² 1229 R¹⁴ G³⁰ W⁴² 1230 R¹⁵ G³⁰ W⁴² 1231 R¹⁹ G³⁰ W⁴² 1232 R²⁷ G³⁰ W⁴² 1233 R²⁸ G³⁰ W⁴² 1234 R³³ G³⁰ W⁴² 1235 R³⁸ G³⁰ W⁴² 1236 R³⁹ G³⁰ W⁴² 1237 R⁴¹ G³⁰ W⁴² 1238 R⁴⁶ G³⁰ W⁴² 1239 R⁴⁷ G³⁰ W⁴² 1240 R⁴⁹ G³⁰ W⁴² 1241 R¹ G³¹ W⁴² 1242 R² G³¹ W⁴² 1243 R⁴ G³¹ W⁴² 1244 R⁵ G³¹ W⁴² 1245 R⁷ G³¹ W⁴² 1246 R⁸ G³¹ W⁴² 1247 R¹⁰ G³¹ W⁴² 1248 R¹² G³¹ W⁴² 1249 R¹⁴ G³¹ W⁴² 1250 R¹⁵ G³¹ W⁴² 1251 R¹⁹ G³¹ W⁴² 1252 R²⁷ G³¹ W⁴² 1253 R²⁸ G³¹ W⁴² 1254 R³³ G³¹ W⁴² 1255 R³⁸ G³¹ W⁴² 1256 R³⁹ G³¹ W⁴² 1257 R⁴¹ G³¹ W⁴² 1258 R⁴⁶ G³¹ W⁴² 1259 R⁴⁷ G³¹ W⁴² 1260 R⁴⁹ G³¹ W⁴² 1261 R¹ G³² W⁴² 1262 R² G³² W⁴² 1263 R⁴ G³² W⁴² 1264 R⁵ G³² W⁴² 1265 R⁷ G³² W⁴² 1266 R⁸ G³² W⁴² 1267 R¹⁰ G³² W⁴² 1268 R¹² G³² W⁴² 1269 R¹⁴ G³² W⁴² 1270 R¹⁵ G³² W⁴² 1271 R¹⁹ G³² W⁴² 1272 R²⁷ G³² W⁴² 1273 R²⁸ G³² W⁴² 1274 R³³ G³² W⁴² 1275 R³⁸ G³² W⁴² 1276 R³⁹ G³² W⁴² 1277 R⁴¹ G³² W⁴² 1278 R⁴⁶ G³² W⁴² 1279 R⁴⁷ G³² W⁴² 1280 R⁴⁹ G³² W⁴² 1281 R¹ G³³ W⁴² 1282 R² G³³ W⁴² 1283 R⁴ G³³ W⁴² 1284 R⁵ G³³ W⁴² 1285 R⁷ G³³ W⁴² 1286 R⁸ G³³ W⁴² 1287 R¹⁰ G³³ W⁴² 1288 R¹² G³³ W⁴² 1289 R¹⁴ G³³ W⁴² 1290 R¹⁵ G³³ W⁴² 1291 R¹⁹ G³³ W⁴² 1292 R²⁷ G³³ W⁴² 1293 R²⁸ G³³ W⁴² 1294 R³³ G³³ W⁴² 1295 R³⁸ G³³ W⁴² 1296 R³⁹ G³³ W⁴² 1297 R⁴¹ G³³ W⁴² 1298 R⁴⁶ G³³ W⁴² 1299 R⁴⁷ G³³ W⁴² 1300 R⁴⁹ G³³ W⁴² 1301 R¹ G³⁴ W⁴² 1302 R² G³⁴ W⁴² 1303 R⁴ G³⁴ W⁴² 1304 R⁵ G³⁴ W⁴² 1305 R⁷ G³⁴ W⁴² 1306 R⁸ G³⁴ W⁴² 1307 R¹⁰ G³⁴ W⁴² 1308 R¹² G³⁴ W⁴² 1309 R¹⁴ G³⁴ W⁴² 1310 R¹⁵ G³⁴ W⁴² 1311 R¹⁹ G³⁴ W⁴² 1312 R²⁷ G³⁴ W⁴² 1313 R²⁸ G³⁴ W⁴² 1314 R³³ G³⁴ W⁴² 1315 R³⁸ G³⁴ W⁴² 1316 R³⁹ G³⁴ W⁴² 1317 R⁴¹ G³⁴ W⁴² 1318 R⁴⁶ G³⁴ W⁴² 1319 R⁴⁷ G³⁴ W⁴² 1320 R⁴⁹ G³⁴ W⁴² 1321 R¹ G³⁵ W⁴² 1322 R² G³⁵ W⁴² 1323 R⁴ G³⁵ W⁴² 1324 R⁵ G³⁵ W⁴² 1325 R⁷ G³⁵ W⁴² 1326 R⁸ G³⁵ W⁴² 1327 R¹⁰ G³⁵ W⁴² 1328 R¹² G³⁵ W⁴² 1329 R¹⁴ G³⁵ W⁴² 1330 R¹⁵ G³⁵ W⁴² 1331 R¹⁹ G³⁵ W⁴² 1332 R²⁷ G³⁵ W⁴² 1333 R²⁸ G³⁵ W⁴² 1334 R³³ G³⁵ W⁴² 1335 R³⁸ G³⁵ W⁴² 1336 R³⁹ G³⁵ W⁴² 1337 R⁴¹ G³⁵ W⁴² 1338 R⁴⁶ G³⁵ W⁴² 1339 R⁴⁷ G³⁵ W⁴² 1340 R⁴⁹ G³⁵ W⁴² 1341 R¹ G³⁶ W⁴² 1342 R² G³⁶ W⁴² 1343 R⁴ G³⁶ W⁴² 1344 R⁵ G³⁶ W⁴² 1345 R⁷ G³⁶ W⁴² 1346 R⁸ G³⁶ W⁴² 1347 R¹⁰ G³⁶ W⁴² 1348 R¹² G³⁶ W⁴² 1349 R¹⁴ G³⁶ W⁴² 1350 R¹⁵ G³⁶ W⁴² 1351 R¹⁹ G³⁶ W⁴² 1352 R²⁷ G³⁶ W⁴² 1353 R²⁸ G³⁶ W⁴² 1354 R³³ G³⁶ W⁴² 1355 R³⁸ G³⁶ W⁴² 1356 R³⁹ G³⁶ W⁴² 1357 R⁴¹ G³⁶ W⁴² 1358 R⁴⁶ G³⁶ W⁴² 1359 R⁴⁷ G³⁶ W⁴² 1360 R⁴⁹ G³⁶ W⁴² 1361 R¹ G³⁷ W⁴² 1362 R² G³⁷ W⁴² 1363 R⁴ G³⁷ W⁴² 1364 R⁵ G³⁷ W⁴² 1365 R⁷ G³⁷ W⁴² 1366 R⁸ G³⁷ W⁴² 1367 R¹⁰ G³⁷ W⁴² 1368 R¹² G³⁷ W⁴² 1369 R¹⁴ G³⁷ W⁴² 1370 R¹⁵ G³⁷ W⁴² 1371 R¹⁹ G³⁷ W⁴² 1372 R²⁷ G³⁷ W⁴² 1373 R²⁸ G³⁷ W⁴² 1374 R³³ G³⁷ W⁴² 1375 R³⁸ G³⁷ W⁴² 1376 R³⁹ G³⁷ W⁴² 1377 R⁴¹ G³⁷ W⁴² 1378 R⁴⁶ G³⁷ W⁴² 1379 R⁴⁷ G³⁷ W⁴² 1380 R⁴⁹ G³⁷ W⁴² 1381 R¹ G³⁹ W⁴² 1382 R² G³⁹ W⁴² 1383 R⁴ G³⁹ W⁴² 1384 R⁵ G³⁹ W⁴² 1385 R⁷ G³⁹ W⁴² 1386 R⁸ G³⁹ W⁴² 1387 R¹⁰ G³⁹ W⁴² 1388 R¹² G³⁹ W⁴² 1389 R¹⁴ G³⁹ W⁴² 1390 R¹⁵ G³⁹ W⁴² 1391 R¹⁹ G³⁹ W⁴² 1392 R²⁷ G³⁹ W⁴² 1393 R²⁸ G³⁹ W⁴² 1394 R³³ G³⁹ W⁴² 1395 R³⁸ G³⁹ W⁴² 1396 R³⁹ G³⁹ W⁴² 1397 R⁴¹ G³⁹ W⁴² 1398 R⁴⁶ G³⁹ W⁴² 1399 R⁴⁷ G³⁹ W⁴² 1400 R⁴⁹ G³⁹ W⁴² 1401 R¹ G¹⁴ W¹ 1402 R² G¹⁴ W¹ 1403 R⁴ G¹⁴ W¹ 1404 R⁵ G¹⁴ W¹ 1405 R⁷ G¹⁴ W¹ 1406 R⁸ G¹⁴ W¹ 1407 R¹⁰ G¹⁴ W¹ 1408 R¹² G¹⁴ W¹ 1409 R¹⁴ G¹⁴ W¹ 1410 R¹⁵ G¹⁴ W¹ 1411 R¹⁹ G¹⁴ W¹ 1412 R²⁷ G¹⁴ W¹ 1413 R²⁸ G¹⁴ W¹ 1414 R³³ G¹⁴ W¹ 1415 R³⁸ G¹⁴ W¹ 1416 R³⁹ G¹⁴ W¹ 1417 R⁴¹ G¹⁴ W¹ 1418 R⁴⁶ G¹⁴ W¹ 1419 R⁴⁷ G¹⁴ W¹ 1420 R⁴⁹ G¹⁴ W¹ 1421 R¹ G¹⁵ W¹ 1422 R² G¹⁵ W¹ 1423 R⁴ G¹⁵ W¹ 1424 R⁵ G¹⁵ W¹ 1425 R⁷ G¹⁵ W¹ 1426 R⁸ G¹⁵ W¹ 1427 R¹⁰ G¹⁵ W¹ 1428 R¹² G¹⁵ W¹ 1429 R¹⁴ G¹⁵ W¹ 1430 R¹⁵ G¹⁵ W¹ 1431 R¹⁹ G¹⁵ W¹ 1432 R²⁷ G¹⁵ W¹ 1433 R²⁸ G¹⁵ W¹ 1434 R³³ G¹⁵ W¹ 1435 R³⁸ G¹⁵ W¹ 1436 R³⁹ G¹⁵ W¹ 1437 R⁴¹ G¹⁵ W¹ 1438 R⁴⁶ G¹⁵ W¹ 1439 R⁴⁷ G¹⁵ W¹ 1440 R⁴⁹ G¹⁵ W¹ 1441 R¹ G¹⁹ W¹ 1442 R² G¹⁹ W¹ 1443 R⁴ G¹⁹ W¹ 1444 R⁵ G¹⁹ W¹ 1445 R⁷ G¹⁹ W¹ 1446 R⁸ G¹⁹ W¹ 1447 R¹⁰ G¹⁹ W¹ 1448 R¹² G¹⁹ W¹ 1449 R¹⁴ G¹⁹ W¹ 1450 R¹⁵ G¹⁹ W¹ 1451 R¹⁹ G¹⁹ W¹ 1452 R²⁷ G¹⁹ W¹ 1453 R²⁸ G¹⁹ W¹ 1454 R³³ G¹⁹ W¹ 1455 R³⁸ G¹⁹ W¹ 1456 R³⁹ G¹⁹ W¹ 1457 R⁴¹ G¹⁹ W¹ 1458 R⁴⁶ G¹⁹ W¹ 1459 R⁴⁷ G¹⁹ W¹ 1460 R⁴⁹ G¹⁹ W¹ 1461 R¹ G²⁰ W¹ 1462 R² G²⁰ W¹ 1463 R⁴ G²⁰ W¹ 1464 R⁵ G²⁰ W¹ 1465 R⁷ G²⁰ W¹ 1466 R⁸ G²⁰ W¹ 1467 R¹⁰ G²⁰ W¹ 1468 R¹² G²⁰ W¹ 1469 R¹⁴ G²⁰ W¹ 1470 R¹⁵ G²⁰ W¹ 1471 R¹⁹ G²⁰ W¹ 1472 R²⁷ G²⁰ W¹ 1473 R²⁸ G²⁰ W¹ 1474 R³³ G²⁰ W¹ 1475 R³⁸ G²⁰ W¹ 1476 R³⁹ G²⁰ W¹ 1477 R⁴¹ G²⁰ W¹ 1478 R⁴⁶ G²⁰ W¹ 1479 R⁴⁷ G²⁰ W¹ 1480 R⁴⁹ G²⁰ W¹ 1481 R¹ G¹⁴ W¹¹ 1482 R² G¹⁴ W¹¹ 1483 R⁴ G¹⁴ W¹¹ 1484 R⁵ G¹⁴ W¹¹ 1485 R⁷ G¹⁴ W¹¹ 1486 R⁸ G¹⁴ W¹¹ 1487 R¹⁰ G¹⁴ W¹¹ 1488 R¹² G¹⁴ W¹¹ 1489 R¹⁴ G¹⁴ W¹¹ 1490 R¹⁵ G¹⁴ W¹¹ 1491 R¹⁹ G¹⁴ W¹¹ 1492 R²⁷ G¹⁴ W¹¹ 1493 R²⁸ G¹⁴ W¹¹ 1494 R³³ G¹⁴ W¹¹ 1495 R³⁸ G¹⁴ W¹¹ 1496 R³⁹ G¹⁴ W¹¹ 1497 R⁴¹ G¹⁴ W¹¹ 1498 R⁴⁶ G¹⁴ W¹¹ 1499 R⁴⁷ G¹⁴ W¹¹ 1500 R⁴⁹ G¹⁴ W¹¹ 1501 R¹ G¹⁵ W¹¹ 1502 R² G¹⁵ W¹¹ 1503 R⁴ G¹⁵ W¹¹ 1504 R⁵ G¹⁵ W¹¹ 1505 R⁷ G¹⁵ W¹¹ 1506 R⁸ G¹⁵ W¹¹ 1507 R¹⁰ G¹⁵ W¹¹ 1508 R¹² G¹⁵ W¹¹ 1509 R¹⁴ G¹⁵ W¹¹ 1510 R¹⁵ G¹⁵ W¹¹ 1511 R¹⁹ G¹⁵ W¹¹ 1512 R²⁷ G¹⁵ W¹¹ 1513 R²⁸ G¹⁵ W¹¹ 1514 R³³ G¹⁵ W¹¹ 1515 R³⁸ G¹⁵ W¹¹ 1516 R³⁹ G¹⁵ W¹¹ 1517 R⁴¹ G¹⁵ W¹¹ 1518 R⁴⁶ G¹⁵ W¹¹ 1519 R⁴⁷ G¹⁵ W¹¹ 1520 R⁴⁹ G¹⁵ W¹¹ 1521 R¹ G¹⁹ W¹¹ 1522 R² G¹⁹ W¹¹ 1523 R⁴ G¹⁹ W¹¹ 1524 R⁵ G¹⁹ W¹¹ 1525 R⁷ G¹⁹ W¹¹ 1526 R⁸ G¹⁹ W¹¹ 1527 R¹⁰ G¹⁹ W¹¹ 1528 R¹² G¹⁹ W¹¹ 1529 R¹⁴ G¹⁹ W¹¹ 1530 R¹⁵ G¹⁹ W¹¹ 1531 R¹⁹ G¹⁹ W¹¹ 1532 R²⁷ G¹⁹ W¹¹ 1533 R²⁸ G¹⁹ W¹¹ 1534 R³³ G¹⁹ W¹¹ 1535 R³⁸ G¹⁹ W¹¹ 1536 R³⁹ G¹⁹ W¹¹ 1537 R⁴¹ G¹⁹ W¹¹ 1538 R⁴⁶ G¹⁹ W¹¹ 1539 R⁴⁷ G¹⁹ W¹¹ 1540 R⁴⁹ G¹⁹ W¹¹ 1541 R¹ G²⁰ W¹¹ 1542 R² G²⁰ W¹¹ 1543 R⁴ G²⁰ W¹¹ 1544 R⁵ G²⁰ W¹¹ 1545 R⁷ G²⁰ W¹¹ 1546 R⁸ G²⁰ W¹¹ 1547 R¹⁰ G²⁰ W¹¹ 1548 R¹² G²⁰ W¹¹ 1549 R¹⁴ G²⁰ W¹¹ 1550 R¹⁵ G²⁰ W¹¹ 1551 R¹⁹ G²⁰ W¹¹ 1552 R²⁷ G²⁰ W¹¹ 1553 R²⁸ G²⁰ W¹¹ 1554 R³³ G²⁰ W¹¹ 1555 R³⁸ G²⁰ W¹¹ 1556 R³⁹ G²⁰ W¹¹ 1557 R⁴¹ G²⁰ W¹¹ 1558 R⁴⁶ G²⁰ W¹¹ 1559 R⁴⁷ G²⁰ W¹¹ 1560 R⁴⁹ G²⁰ W¹¹ 1561 R¹ G² W¹ 1562 R² G² W¹ 1563 R³ G² W¹ 1564 R⁴ G² W¹ 1565 R⁵ G² W¹ 1566 R⁶ G² W¹ 1567 R⁷ G² W¹ 1568 R⁸ G² W¹ 1569 R⁹ G² W¹ 1570 R¹⁰ G² W¹ 1571 R¹¹ G² W¹ 1572 R¹² G² W¹ 1573 R¹³ G² W¹ 1574 R¹⁴ G² W¹ 1575 R¹⁵ G² W¹ 1576 R¹⁶ G² W¹ 1577 R¹⁷ G² W¹ 1578 R¹⁸ G² W¹ 1579 R¹⁹ G² W¹ 1580 R²⁰ G² W¹ 1581 R²¹ G² W¹ 1582 R²² G² W¹ 1583 R²³ G² W¹ 1584 R²⁴ G² W¹ 1585 R²⁵ G² W¹ 1586 R²⁶ G² W¹ 1587 R²⁷ G² W¹ 1588 R²⁸ G² W¹ 1589 R²⁹ G² W¹ 1590 R³⁰ G² W¹ 1591 R³¹ G² W¹ 1592 R³² G² W¹ 1593 R³³ G² W¹ 1594 R³⁴ G² W¹ 1595 R³⁵ G² W¹ 1596 R³⁶ G² W¹ 1597 R³⁷ G² W¹ 1598 R³⁸ G² W¹ 1599 R³⁹ G² W¹ 1600 R⁴⁰ G² W¹ 1601 R⁴¹ G² W¹ 1602 R⁴² G² W¹ 1603 R⁴³ G² W¹ 1604 R⁴⁴ G² W¹ 1605 R⁴⁵ G² W¹ 1606 R⁴⁶ G² W¹ 1607 R⁴⁷ G² W¹ 1608 R⁴⁸ G² W¹ 1609 R⁴⁹ G² W¹ 1610 R⁵⁰ G² W¹ 1611 R¹ G⁴ W¹ 1612 R² G⁴ W¹ 1613 R³ G⁴ W¹ 1614 R⁴ G⁴ W¹ 1615 R⁵ G⁴ W¹ 1616 R⁶ G⁴ W¹ 1617 R⁷ G⁴ W¹ 1618 R⁸ G⁴ W¹ 1619 R⁹ G⁴ W¹ 1620 R¹⁰ G⁴ W¹ 1621 R¹¹ G⁴ W¹ 1622 R¹² G⁴ W¹ 1623 R¹³ G⁴ W¹ 1624 R¹⁴ G⁴ W¹ 1625 R¹⁵ G⁴ W¹ 1626 R¹⁶ G⁴ W¹ 1627 R¹⁷ G⁴ W¹ 1628 R¹⁸ G⁴ W¹ 1629 R¹⁹ G⁴ W¹ 1630 R²⁰ G⁴ W¹ 1631 R²¹ G⁴ W¹ 1632 R²² G⁴ W¹ 1633 R²³ G⁴ W¹ 1634 R²⁴ G⁴ W¹ 1635 R²⁵ G⁴ W¹ 1636 R²⁶ G⁴ W¹ 1637 R²⁷ G⁴ W¹ 1638 R²⁸ G⁴ W¹ 1639 R²⁹ G⁴ W¹ 1640 R³⁰ G⁴ W¹ 1641 R³¹ G⁴ W¹ 1642 R³² G⁴ W¹ 1643 R³³ G⁴ W¹ 1644 R³⁴ G⁴ W¹ 1645 R³⁵ G⁴ W¹ 1646 R³⁶ G⁴ W¹ 1647 R³⁷ G⁴ W¹ 1648 R³⁸ G⁴ W¹ 1649 R³⁹ G⁴ W¹ 1650 R⁴⁰ G⁴ W¹ 1651 R⁴¹ G⁴ W¹ 1652 R⁴² G⁴ W¹ 1653 R⁴³ G⁴ W¹ 1654 R⁴⁴ G⁴ W¹ 1655 R⁴⁵ G⁴ W¹ 1656 R⁴⁶ G⁴ W¹ 1657 R⁴⁷ G⁴ W¹ 1658 R⁴⁸ G⁴ W¹ 1659 R⁴⁹ G⁴ W¹ 1660 R⁵⁰ G⁴ W¹ 1661 R¹ G² W¹¹ 1662 R² G² W¹¹ 1663 R³ G² W¹¹ 1664 R⁴ G² W¹¹ 1665 R⁵ G² W¹¹ 1666 R⁶ G² W¹¹ 1667 R⁷ G² W¹¹ 1668 R⁸ G² W¹¹ 1669 R⁹ G² W¹¹ 1670 R¹⁰ G² W¹¹ 1671 R¹¹ G² W¹¹ 1672 R¹² G² W¹¹ 1673 R¹³ G² W¹¹ 1674 R¹⁴ G² W¹¹ 1675 R¹⁵ G² W¹¹ 1676 R¹⁶ G² W¹¹ 1677 R¹⁷ G² W¹¹ 1678 R¹⁸ G² W¹¹ 1679 R¹⁹ G² W¹¹ 1680 R²⁰ G² W¹¹ 1681 R²¹ G² W¹¹ 1682 R²² G² W¹¹ 1683 R²³ G² W¹¹ 1684 R²⁴ G² W¹¹ 1685 R²⁵ G² W¹¹ 1686 R²⁶ G² W¹¹ 1687 R²⁷ G² W¹¹ 1688 R²⁸ G² W¹¹ 1689 R²⁹ G² W¹¹ 1690 R³⁰ G² W¹¹ 1691 R³¹ G² W¹¹ 1692 R³² G² W¹¹ 1693 R³³ G² W¹¹ 1694 R³⁴ G² W¹¹ 1695 R³⁵ G² W¹¹ 1696 R³⁶ G² W¹¹ 1697 R³⁷ G² W¹¹ 1698 R³⁸ G² W¹¹ 1699 R³⁹ G² W¹¹ 1700 R⁴⁰ G² W¹¹ 1701 R⁴¹ G² W¹¹ 1702 R⁴² G² W¹¹ 1703 R⁴³ G² W¹¹ 1704 R⁴⁴ G² W¹¹ 1705 R⁴⁵ G² W¹¹ 1706 R⁴⁶ G² W¹¹ 1707 R⁴⁷ G² W¹¹ 1708 R⁴⁸ G² W¹¹ 1709 R⁴⁹ G² W¹¹ 1710 R⁵⁰ G² W¹¹ 1711 R¹ G⁴ W¹¹ 1712 R² G⁴ W¹¹ 1713 R³ G⁴ W¹¹ 1714 R⁴ G⁴ W¹¹ 1715 R⁵ G⁴ W¹¹ 1716 R⁶ G⁴ W¹¹ 1717 R⁷ G⁴ W¹¹ 1718 R⁸ G⁴ W¹¹ 1719 R⁹ G⁴ W¹¹ 1720 R¹⁰ G⁴ W¹¹ 1721 R¹¹ G⁴ W¹¹ 1722 R¹² G⁴ W¹¹ 1723 R¹³ G⁴ W¹¹ 1724 R¹⁴ G⁴ W¹¹ 1725 R¹⁵ G⁴ W¹¹ 1726 R¹⁶ G⁴ W¹¹ 1727 R¹⁷ G⁴ W¹¹ 1728 R¹⁸ G⁴ W¹¹ 1729 R¹⁹ G⁴ W¹¹ 1730 R²⁰ G⁴ W¹¹ 1731 R²¹ G⁴ W¹¹ 1732 R²² G⁴ W¹¹ 1733 R²³ G⁴ W¹¹ 1734 R²⁴ G⁴ W¹¹ 1735 R²⁵ G⁴ W¹¹ 1736 R²⁶ G⁴ W¹¹ 1737 R²⁷ G⁴ W¹¹ 1738 R²⁸ G⁴ W¹¹ 1739 R²⁹ G⁴ W¹¹ 1740 R³⁰ G⁴ W¹¹ 1741 R³¹ G⁴ W¹¹ 1742 R³² G⁴ W¹¹ 1743 R³³ G⁴ W¹¹ 1744 R³⁴ G⁴ W¹¹ 1745 R³⁵ G⁴ W¹¹ 1746 R³⁶ G⁴ W¹¹ 1747 R³⁷ G⁴ W¹¹ 1748 R³⁸ G⁴ W¹¹ 1749 R³⁹ G⁴ W¹¹ 1750 R⁴⁰ G⁴ W¹¹ 1751 R⁴¹ G⁴ W¹¹ 1752 R⁴² G⁴ W¹¹ 1753 R⁴³ G⁴ W¹¹ 1754 R⁴⁴ G⁴ W¹¹ 1755 R⁴⁵ G⁴ W¹¹ 1756 R⁴⁶ G⁴ W¹¹ 1757 R⁴⁷ G⁴ W¹¹ 1758 R⁴⁸ G⁴ W¹¹ 1759 R⁴⁹ G⁴ W¹¹ 1760 R⁵⁰ G⁴ W¹¹ 1761 R¹ G² W²¹ 1762 R² G² W²¹ 1763 R³ G² W²¹ 1764 R⁴ G² W²¹ 1765 R⁵ G² W²¹ 1766 R⁶ G² W²¹ 1767 R⁷ G² W²¹ 1768 R⁸ G² W²¹ 1769 R⁹ G² W²¹ 1770 R¹⁰ G² W²¹ 1771 R¹¹ G² W²¹ 1772 R¹² G² W²¹ 1773 R¹³ G² W²¹ 1774 R¹⁴ G² W²¹ 1775 R¹⁵ G² W²¹ 1776 R¹⁶ G² W²¹ 1777 R¹⁷ G² W²¹ 1778 R¹⁸ G² W²¹ 1779 R¹⁹ G² W²¹ 1780 R²⁰ G² W²¹ 1781 R²¹ G² W²¹ 1782 R²² G² W²¹ 1783 R²³ G² W²¹ 1784 R²⁴ G² W²¹ 1785 R²⁵ G² W²¹ 1786 R²⁶ G² W²¹ 1787 R²⁷ G² W²¹ 1788 R²⁸ G² W²¹ 1789 R²⁹ G² W²¹ 1790 R³⁰ G² W²¹ 1791 R³¹ G² W²¹ 1792 R³² G² W²¹ 1793 R³³ G² W²¹ 1794 R³⁴ G² W²¹ 1795 R³⁵ G² W²¹ 1796 R³⁶ G² W²¹ 1797 R³⁷ G² W²¹ 1798 R³⁸ G² W²¹ 1799 R³⁹ G² W²¹ 1800 R⁴⁰ G² W²¹ 1801 R⁴¹ G² W²¹ 1802 R⁴² G² W²¹ 1803 R⁴³ G² W²¹ 1804 R⁴⁴ G² W²¹ 1805 R⁴⁵ G² W²¹ 1806 R⁴⁶ G² W²¹ 1807 R⁴⁷ G² W²¹ 1808 R⁴⁸ G² W²¹ 1809 R⁴⁹ G² W²¹ 1810 R⁵⁰ G² W²¹ 1811 R¹ G⁴ W²¹ 1812 R² G⁴ W²¹ 1813 R³ G⁴ W²¹ 1814 R⁴ G⁴ W²¹ 1815 R⁵ G⁴ W²¹ 1816 R⁶ G⁴ W²¹ 1817 R⁷ G⁴ W²¹ 1818 R⁸ G⁴ W²¹ 1819 R⁹ G⁴ W²¹ 1820 R¹⁰ G⁴ W²¹ 1821 R¹¹ G⁴ W²¹ 1822 R¹² G⁴ W²¹ 1823 R¹³ G⁴ W²¹ 1824 R¹⁴ G⁴ W²¹ 1825 R¹⁵ G⁴ W²¹ 1826 R¹⁶ G⁴ W²¹ 1827 R¹⁷ G⁴ W²¹ 1828 R¹⁸ G⁴ W²¹ 1829 R¹⁹ G⁴ W²¹ 1830 R²⁰ G⁴ W²¹ 1831 R²¹ G⁴ W²¹ 1832 R²² G⁴ W²¹ 1833 R²³ G⁴ W²¹ 1834 R²⁴ G⁴ W²¹ 1835 R²⁵ G⁴ W²¹ 1836 R²⁶ G⁴ W²¹ 1837 R²⁷ G⁴ W²¹ 1838 R²⁸ G⁴ W²¹ 1839 R²⁹ G⁴ W²¹ 1840 R³⁰ G⁴ W²¹ 1841 R³¹ G⁴ W²¹ 1842 R³² G⁴ W²¹ 1843 R³³ G⁴ W²¹ 1844 R³⁴ G⁴ W²¹ 1845 R³⁵ G⁴ W²¹ 1846 R³⁶ G⁴ W²¹ 1847 R³⁷ G⁴ W²¹ 1848 R³⁸ G⁴ W²¹ 1849 R³⁹ G⁴ W²¹ 1850 R⁴⁰ G⁴ W²¹ 1851 R⁴¹ G⁴ W²¹ 1852 R⁴² G⁴ W²¹ 1853 R⁴³ G⁴ W²¹ 1854 R⁴⁴ G⁴ W²¹ 1855 R⁴⁵ G⁴ W²¹ 1856 R⁴⁶ G⁴ W²¹ 1857 R⁴⁷ G⁴ W²¹ 1858 R⁴⁸ G⁴ W²¹ 1859 R⁴⁹ G⁴ W²¹ 1860 R⁵⁰ G⁴ W²¹ 1861 R¹ G² W²⁸ 1862 R² G² W²⁸ 1863 R³ G² W²⁸ 1864 R⁴ G² W²⁸ 1865 R⁵ G² W²⁸ 1866 R⁶ G² W²⁸ 1867 R⁷ G² W²⁸ 1868 R⁸ G² W²⁸ 1869 R⁹ G² W²⁸ 1870 R¹⁰ G² W²⁸ 1871 R¹¹ G² W²⁸ 1872 R¹² G² W²⁸ 1873 R¹³ G² W²⁸ 1874 R¹⁴ G² W²⁸ 1875 R¹⁵ G² W²⁸ 1876 R¹⁶ G² W²⁸ 1877 R¹⁷ G² W²⁸ 1878 R¹⁸ G² W²⁸ 1879 R¹⁹ G² W²⁸ 1880 R²⁰ G² W²⁸ 1881 R²¹ G² W²⁸ 1882 R²² G² W²⁸ 1883 R²³ G² W²⁸ 1884 R²⁴ G² W²⁸ 1885 R²⁵ G² W²⁸ 1886 R²⁶ G² W²⁸ 1887 R²⁷ G² W²⁸ 1888 R²⁸ G² W²⁸ 1889 R²⁹ G² W²⁸ 1890 R³⁰ G² W²⁸ 1891 R³¹ G² W²⁸ 1892 R³² G² W²⁸ 1893 R³³ G² W²⁸ 1894 R³⁴ G² W²⁸ 1895 R³⁵ G² W²⁸ 1896 R³⁶ G² W²⁸ 1897 R³⁷ G² W²⁸ 1898 R³⁸ G² W²⁸ 1899 R³⁹ G² W²⁸ 1900 R⁴⁰ G² W²⁸ 1901 R⁴¹ G² W²⁸ 1902 R⁴² G² W²⁸ 1903 R⁴³ G² W²⁸ 1904 R⁴⁴ G² W²⁸ 1905 R⁴⁵ G² W²⁸ 1906 R⁴⁶ G² W²⁸ 1907 R⁴⁷ G² W²⁸ 1908 R⁴⁸ G² W²⁸ 1909 R⁴⁹ G² W²⁸ 1910 R⁵⁰ G² W²⁸ 1911 R¹ G⁴ W²⁸ 1912 R² G⁴ W²⁸ 1913 R³ G⁴ W²⁸ 1914 R⁴ G⁴ W²⁸ 1915 R⁵ G⁴ W²⁸ 1916 R⁶ G⁴ W²⁸ 1917 R⁷ G⁴ W²⁸ 1918 R⁸ G⁴ W²⁸ 1919 R⁹ G⁴ W²⁸ 1920 R¹⁰ G⁴ W²⁸ 1921 R¹¹ G⁴ W²⁸ 1922 R¹² G⁴ W²⁸ 1923 R¹³ G⁴ W²⁸ 1924 R¹⁴ G⁴ W²⁸ 1925 R¹⁵ G⁴ W²⁸ 1926 R¹⁶ G⁴ W²⁸ 1927 R¹⁷ G⁴ W²⁸ 1928 R¹⁸ G⁴ W²⁸ 1929 R¹⁹ G⁴ W²⁸ 1930 R²⁰ G⁴ W²⁸ 1931 R²¹ G⁴ W²⁸ 1932 R²² G⁴ W²⁸ 1933 R²³ G⁴ W²⁸ 1934 R²⁴ G⁴ W²⁸ 1935 R²⁵ G⁴ W²⁸ 1936 R²⁶ G⁴ W²⁸ 1937 R²⁷ G⁴ W²⁸ 1938 R²⁸ G⁴ W²⁸ 1939 R²⁹ G⁴ W²⁸ 1940 R³⁰ G⁴ W²⁸ 1941 R³¹ G⁴ W²⁸ 1942 R³² G⁴ W²⁸ 1943 R³³ G⁴ W²⁸ 1944 R³⁴ G⁴ W²⁸ 1945 R³⁵ G⁴ W²⁸ 1946 R³⁶ G⁴ W²⁸ 1947 R³⁷ G⁴ W²⁸ 1948 R³⁸ G⁴ W²⁸ 1949 R³⁹ G⁴ W²⁸ 1950 R⁴⁰ G⁴ W²⁸ 1951 R⁴¹ G⁴ W²⁸ 1952 R⁴² G⁴ W²⁸ 1953 R⁴³ G⁴ W²⁸ 1954 R⁴⁴ G⁴ W²⁸ 1955 R⁴⁵ G⁴ W²⁸ 1956 R⁴⁶ G⁴ W²⁸ 1957 R⁴⁷ G⁴ W²⁸ 1958 R⁴⁸ G⁴ W²⁸ 1959 R⁴⁹ G⁴ W²⁸ 1960 R⁵⁰ G⁴ W²⁸ 1961 R¹ G² W³⁶ 1962 R² G² W³⁶ 1963 R³ G² W³⁶ 1964 R⁴ G² W³⁶ 1965 R⁵ G² W³⁶ 1966 R⁶ G² W³⁶ 1967 R⁷ G² W³⁶ 1968 R⁸ G² W³⁶ 1969 R⁹ G² W³⁶ 1970 R¹⁰ G² W³⁶ 1971 R¹¹ G² W³⁶ 1972 R¹² G² W³⁶ 1973 R¹³ G² W³⁶ 1974 R¹⁴ G² W³⁶ 1975 R¹⁵ G² W³⁶ 1976 R¹⁶ G² W³⁶ 1977 R¹⁷ G² W³⁶ 1978 R¹⁸ G² W³⁶ 1979 R¹⁹ G² W³⁶ 1980 R²⁰ G² W³⁶ 1981 R²¹ G² W³⁶ 1982 R²² G² W³⁶ 1983 R²³ G² W³⁶ 1984 R²⁴ G² W³⁶ 1985 R²⁵ G² W³⁶ 1986 R²⁶ G² W³⁶ 1987 R²⁷ G² W³⁶ 1988 R²⁸ G² W³⁶ 1989 R²⁹ G² W³⁶ 1990 R³⁰ G² W³⁶ 1991 R³¹ G² W³⁶ 1992 R³² G² W³⁶ 1993 R³³ G² W³⁶ 1994 R³⁴ G² W³⁶ 1995 R³⁵ G² W³⁶ 1996 R³⁶ G² W³⁶ 1997 R³⁷ G² W³⁶ 1998 R³⁸ G² W³⁶ 1999 R³⁹ G² W³⁶ 2000 R⁴⁰ G² W³⁶ 2001 R⁴¹ G² W³⁶ 2002 R⁴² G² W³⁶ 2003 R⁴³ G² W³⁶ 2004 R⁴⁴ G² W³⁶ 2005 R⁴⁵ G² W³⁶ 2006 R⁴⁶ G² W³⁶ 2007 R⁴⁷ G² W³⁶ 2008 R⁴⁸ G² W³⁶ 2009 R⁴⁹ G² W³⁶ 2010 R⁵⁰ G² W³⁶ 2011 R¹ G⁴ W³⁶ 2012 R² G⁴ W³⁶ 2013 R³ G⁴ W³⁶ 2014 R⁴ G⁴ W³⁶ 2015 R⁵ G⁴ W³⁶ 2016 R⁶ G⁴ W³⁶ 2017 R⁷ G⁴ W³⁶ 2018 R⁸ G⁴ W³⁶ 2019 R⁹ G⁴ W³⁶ 2020 R¹⁰ G⁴ W³⁶ 2021 R¹¹ G⁴ W³⁶ 2022 R¹² G⁴ W³⁶ 2023 R¹³ G⁴ W³⁶ 2024 R¹⁴ G⁴ W³⁶ 2025 R¹⁵ G⁴ W³⁶ 2026 R¹⁶ G⁴ W³⁶ 2027 R¹⁷ G⁴ W³⁶ 2028 R¹⁸ G⁴ W³⁶ 2029 R¹⁹ G⁴ W³⁶ 2030 R²⁰ G⁴ W³⁶ 2031 R²¹ G⁴ W³⁶ 2032 R²² G⁴ W³⁶ 2033 R²³ G⁴ W³⁶ 2034 R²⁴ G⁴ W³⁶ 2035 R²⁵ G⁴ W³⁶ 2036 R²⁶ G⁴ W³⁶ 2037 R²⁷ G⁴ W³⁶ 2038 R²⁸ G⁴ W³⁶ 2039 R²⁹ G⁴ W³⁶ 2040 R³⁰ G⁴ W³⁶ 2041 R³¹ G⁴ W³⁶ 2042 R³² G⁴ W³⁶ 2043 R³³ G⁴ W³⁶ 2044 R³⁴ G⁴ W³⁶ 2045 R³⁵ G⁴ W³⁶ 2046 R³⁶ G⁴ W³⁶ 2047 R³⁷ G⁴ W³⁶ 2048 R³⁸ G⁴ W³⁶ 2049 R³⁹ G⁴ W³⁶ 2050 R⁴⁰ G⁴ W³⁶ 2051 R⁴¹ G⁴ W³⁶ 2052 R⁴² G⁴ W³⁶ 2053 R⁴³ G⁴ W³⁶ 2054 R⁴⁴ G⁴ W³⁶ 2055 R⁴⁵ G⁴ W³⁶ 2056 R⁴⁶ G⁴ W³⁶ 2057 R⁴⁷ G⁴ W³⁶ 2058 R⁴⁸ G⁴ W³⁶ 2059 R⁴⁹ G⁴ W³⁶ 2060 R⁵⁰ G⁴ W³⁶ 2061 R¹ G² W³⁷ 2062 R² G² W³⁷ 2063 R³ G² W³⁷ 2064 R⁴ G² W³⁷ 2065 R⁵ G² W³⁷ 2066 R⁶ G² W³⁷ 2067 R⁷ G² W³⁷ 2068 R⁸ G² W³⁷ 2069 R⁹ G² W³⁷ 2070 R¹⁰ G² W³⁷ 2071 R¹¹ G² W³⁷ 2072 R¹² G² W³⁷ 2073 R¹³ G² W³⁷ 2074 R¹⁴ G² W³⁷ 2075 R¹⁵ G² W³⁷ 2076 R¹⁶ G² W³⁷ 2077 R¹⁷ G² W³⁷ 2078 R¹⁸ G² W³⁷ 2079 R¹⁹ G² W³⁷ 2080 R²⁰ G² W³⁷ 2081 R²¹ G² W³⁷ 2082 R²² G² W³⁷ 2083 R²³ G² W³⁷ 2084 R²⁴ G² W³⁷ 2085 R²⁵ G² W³⁷ 2086 R²⁶ G² W³⁷ 2087 R²⁷ G² W³⁷ 2088 R²⁸ G² W³⁷ 2089 R²⁹ G² W³⁷ 2090 R³⁰ G² W³⁷ 2091 R³¹ G² W³⁷ 2092 R³² G² W³⁷ 2093 R³³ G² W³⁷ 2094 R³⁴ G² W³⁷ 2095 R³⁵ G² W³⁷ 2096 R³⁶ G² W³⁷ 2097 R³⁷ G² W³⁷ 2098 R³⁸ G² W³⁷ 2099 R³⁹ G² W³⁷ 2100 R⁴⁰ G² W³⁷ 2101 R⁴¹ G² W³⁷ 2102 R⁴² G² W³⁷ 2103 R⁴³ G² W³⁷ 2104 R⁴⁴ G² W³⁷ 2105 R⁴⁵ G² W³⁷ 2106 R⁴⁶ G² W³⁷ 2107 R⁴⁷ G² W³⁷ 2108 R⁴⁸ G² W³⁷ 2109 R⁴⁹ G² W³⁷ 2110 R⁵⁰ G² W³⁷ 2111 R¹ G⁴ W³⁷ 2112 R² G⁴ W³⁷ 2113 R³ G⁴ W³⁷ 2114 R⁴ G⁴ W³⁷ 2115 R⁵ G⁴ W³⁷ 2116 R⁶ G⁴ W³⁷ 2117 R⁷ G⁴ W³⁷ 2118 R⁸ G⁴ W³⁷ 2119 R⁹ G⁴ W³⁷ 2120 R¹⁰ G⁴ W³⁷ 2121 R¹¹ G⁴ W³⁷ 2122 R¹² G⁴ W³⁷ 2123 R¹³ G⁴ W³⁷ 2124 R¹⁴ G⁴ W³⁷ 2125 R¹⁵ G⁴ W³⁷ 2126 R¹⁶ G⁴ W³⁷ 2127 R¹⁷ G⁴ W³⁷ 2128 R¹⁸ G⁴ W³⁷ 2129 R¹⁹ G⁴ W³⁷ 2130 R²⁰ G⁴ W³⁷ 2131 R²¹ G⁴ W³⁷ 2132 R²² G⁴ W³⁷ 2133 R²³ G⁴ W³⁷ 2134 R²⁴ G⁴ W³⁷ 2135 R²⁵ G⁴ W³⁷ 2136 R²⁶ G⁴ W³⁷ 2137 R²⁷ G⁴ W³⁷ 2138 R²⁸ G⁴ W³⁷ 2139 R²⁹ G⁴ W³⁷ 2140 R³⁰ G⁴ W³⁷ 2141 R³¹ G⁴ W³⁷ 2142 R³² G⁴ W³⁷ 2143 R³³ G⁴ W³⁷ 2144 R³⁴ G⁴ W³⁷ 2145 R³⁵ G⁴ W³⁷ 2146 R³⁶ G⁴ W³⁷ 2147 R³⁷ G⁴ W³⁷ 2148 R³⁸ G⁴ W³⁷ 2149 R³⁹ G⁴ W³⁷ 2150 R⁴⁰ G⁴ W³⁷ 2151 R⁴¹ G⁴ W³⁷ 2152 R⁴² G⁴ W³⁷ 2153 R⁴³ G⁴ W³⁷ 2154 R⁴⁴ G⁴ W³⁷ 2155 R⁴⁵ G⁴ W³⁷ 2156 R⁴⁶ G⁴ W³⁷ 2157 R⁴⁷ G⁴ W³⁷ 2158 R⁴⁸ G⁴ W³⁷ 2159 R⁴⁹ G⁴ W³⁷ 2160 R⁵⁰ G⁴ W³⁷ 2161 R¹ G¹ W¹ 2162 R² G¹ W¹ 2163 R⁴ G¹ W¹ 2164 R⁵ G¹ W¹ 2165 R⁷ G¹ W¹ 2166 R⁸ G¹ W¹ 2167 R¹⁰ G¹ W¹ 2168 R¹² G¹ W¹ 2169 R¹⁴ G¹ W¹ 2170 R¹⁵ G¹ W¹ 2171 R¹⁹ G¹ W¹ 2172 R²⁷ G¹ W¹ 2173 R²⁸ G¹ W¹ 2174 R³³ G¹ W¹ 2175 R³⁸ G¹ W¹ 2176 R³⁹ G¹ W¹ 2177 R⁴¹ G¹ W¹ 2178 R⁴⁶ G¹ W¹ 2179 R⁴⁷ G¹ W¹ 2180 R⁴⁹ G¹ W¹ 2181 R¹ G³ W¹ 2182 R² G³ W¹ 2183 R⁴ G³ W¹ 2184 R⁵ G³ W¹ 2185 R⁷ G³ W¹ 2186 R⁸ G³ W¹ 2187 R¹⁰ G³ W¹ 2188 R¹² G³ W¹ 2189 R¹⁴ G³ W¹ 2190 R¹⁵ G³ W¹ 2191 R¹⁹ G³ W¹ 2192 R²⁷ G³ W¹ 2193 R²⁸ G³ W¹ 2194 R³³ G³ W¹ 2195 R³⁸ G³ W¹ 2196 R³⁹ G³ W¹ 2197 R⁴¹ G³ W¹ 2198 R⁴⁶ G³ W¹ 2199 R⁴⁷ G³ W¹ 2200 R⁴⁹ G³ W¹ 2201 R¹ G⁵ W¹ 2202 R² G⁵ W¹ 2203 R⁴ G⁵ W¹ 2204 R⁵ G⁵ W¹ 2205 R⁷ G⁵ W¹ 2206 R⁸ G⁵ W¹ 2207 R¹⁰ G⁵ W¹ 2208 R¹² G⁵ W¹ 2209 R¹⁴ G⁵ W¹ 2210 R¹⁵ G⁵ W¹ 2211 R¹⁹ G⁵ W¹ 2212 R²⁷ G⁵ W¹ 2213 R²⁸ G⁵ W¹ 2214 R³³ G⁵ W¹ 2215 R³⁸ G⁵ W¹ 2216 R³⁹ G⁵ W¹ 2217 R⁴¹ G⁵ W¹ 2218 R⁴⁶ G⁵ W¹ 2219 R⁴⁷ G⁵ W¹ 2220 R⁴⁹ G⁵ W¹ 2221 R¹ G⁶ W¹ 2222 R² G⁶ W¹ 2223 R⁴ G⁶ W¹ 2224 R⁵ G⁶ W¹ 2225 R⁷ G⁶ W¹ 2226 R⁸ G⁶ W¹ 2227 R¹⁰ G⁶ W¹ 2228 R¹² G⁶ W¹ 2229 R¹⁴ G⁶ W¹ 2230 R¹⁵ G⁶ W¹ 2231 R¹⁹ G⁶ W¹ 2232 R²⁷ G⁶ W¹ 2233 R²⁸ G⁶ W¹ 2234 R³³ G⁶ W¹ 2235 R³⁸ G⁶ W¹ 2236 R³⁹ G⁶ W¹ 2237 R⁴¹ G⁶ W¹ 2238 R⁴⁶ G⁶ W¹ 2239 R⁴⁷ G⁶ W¹ 2240 R⁴⁹ G⁶ W¹ 2241 R¹ G⁹ W¹ 2242 R² G⁹ W¹ 2243 R⁴ G⁹ W¹ 2244 R⁵ G⁹ W¹ 2245 R⁷ G⁹ W¹ 2246 R⁸ G⁹ W¹ 2247 R¹⁰ G⁹ W¹ 2248 R¹² G⁹ W¹ 2249 R¹⁴ G⁹ W¹ 2250 R¹⁵ G⁹ W¹ 2251 R¹⁹ G⁹ W¹ 2252 R²⁷ G⁹ W¹ 2253 R²⁸ G⁹ W¹ 2254 R³³ G⁹ W¹ 2255 R³⁸ G⁹ W¹ 2256 R³⁹ G⁹ W¹ 2257 R⁴¹ G⁹ W¹ 2258 R⁴⁶ G⁹ W¹ 2259 R⁴⁷ G⁹ W¹ 2260 R⁴⁹ G⁹ W¹ 2261 R¹ G¹⁰ W¹ 2262 R² G¹⁰ W¹ 2263 R⁴ G¹⁰ W¹ 2264 R⁵ G¹⁰ W¹ 2265 R⁷ G¹⁰ W¹ 2266 R⁸ G¹⁰ W¹ 2267 R¹⁰ G¹⁰ W¹ 2268 R¹² G¹⁰ W¹ 2269 R¹⁴ G¹⁰ W¹ 2270 R¹⁵ G¹⁰ W¹ 2271 R¹⁹ G¹⁰ W¹ 2272 R²⁷ G¹⁰ W¹ 2273 R²⁸ G¹⁰ W¹ 2274 R³³ G¹⁰ W¹ 2275 R³⁸ G¹⁰ W¹ 2276 R³⁹ G¹⁰ W¹ 2277 R⁴¹ G¹⁰ W¹ 2278 R⁴⁶ G¹⁰ W¹ 2279 R⁴⁷ G¹⁰ W¹ 2280 R⁴⁹ G¹⁰ W¹ 2281 R¹ G²⁵ W¹ 2282 R² G²⁵ W¹ 2283 R⁴ G²⁵ W¹ 2284 R⁵ G²⁵ W¹ 2285 R⁷ G²⁵ W¹ 2286 R⁸ G²⁵ W¹ 2287 R¹⁰ G²⁵ W¹ 2288 R¹² G²⁵ W¹ 2289 R¹⁴ G²⁵ W¹ 2290 R¹⁵ G²⁵ W¹ 2291 R¹⁹ G²⁵ W¹ 2292 R²⁷ G²⁵ W¹ 2293 R²⁸ G²⁵ W¹ 2294 R³³ G²⁵ W¹ 2295 R³⁸ G²⁵ W¹ 2296 R³⁹ G²⁵ W¹ 2297 R⁴¹ G²⁵ W¹ 2298 R⁴⁶ G²⁵ W¹ 2299 R⁴⁷ G²⁵ W¹ 2300 R⁴⁹ G²⁵ W¹ 2301 R¹ G²⁶ W¹ 2302 R² G²⁶ W¹ 2303 R⁴ G²⁶ W¹ 2304 R⁵ G²⁶ W¹ 2305 R⁷ G²⁶ W¹ 2306 R⁸ G²⁶ W¹ 2307 R¹⁰ G²⁶ W¹ 2308 R¹² G²⁶ W¹ 2309 R¹⁴ G²⁶ W¹ 2310 R¹⁵ G²⁶ W¹ 2311 R¹⁹ G²⁶ W¹ 2312 R²⁷ G²⁶ W¹ 2313 R²⁸ G²⁶ W¹ 2314 R³³ G²⁶ W¹ 2315 R³⁸ G²⁶ W¹ 2316 R³⁹ G²⁶ W¹ 2317 R⁴¹ G²⁶ W¹ 2318 R⁴⁶ G²⁶ W¹ 2319 R⁴⁷ G²⁶ W¹ 2320 R⁴⁹ G²⁶ W¹ 2321 R¹ G²⁷ W¹ 2322 R² G²⁷ W¹ 2323 R⁴ G²⁷ W¹ 2324 R⁵ G²⁷ W¹ 2325 R⁷ G²⁷ W¹ 2326 R⁸ G²⁷ W¹ 2327 R¹⁰ G²⁷ W¹ 2328 R¹² G²⁷ W¹ 2329 R¹⁴ G²⁷ W¹ 2330 R¹⁵ G²⁷ W¹ 2331 R¹⁹ G²⁷ W¹ 2332 R²⁷ G²⁷ W¹ 2333 R²⁸ G²⁷ W¹ 2334 R³³ G²⁷ W¹ 2335 R³⁸ G²⁷ W¹ 2336 R³⁹ G²⁷ W¹ 2337 R⁴¹ G²⁷ W¹ 2338 R⁴⁶ G²⁷ W¹ 2339 R⁴⁷ G²⁷ W¹ 2340 R⁴⁹ G²⁷ W¹ 2341 R¹ G²⁸ W¹ 2342 R² G²⁸ W¹ 2343 R⁴ G²⁸ W¹ 2344 R⁵ G²⁸ W¹ 2345 R⁷ G²⁸ W¹ 2346 R⁸ G²⁸ W¹ 2347 R¹⁰ G²⁸ W¹ 2348 R¹² G²⁸ W¹ 2349 R¹⁴ G²⁸ W¹ 2350 R¹⁵ G²⁸ W¹ 2351 R¹⁹ G²⁸ W¹ 2352 R²⁷ G²⁸ W¹ 2353 R²⁸ G²⁸ W¹ 2354 R³³ G²⁸ W¹ 2355 R³⁸ G²⁸ W¹ 2356 R³⁹ G²⁸ W¹ 2357 R⁴¹ G²⁸ W¹ 2358 R⁴⁶ G²⁸ W¹ 2359 R⁴⁷ G²⁸ W¹ 2360 R⁴⁹ G²⁸ W¹ 2361 R¹ G¹ W² 2362 R² G¹ W² 2363 R⁴ G¹ W² 2364 R⁵ G¹ W² 2365 R⁷ G¹ W² 2366 R⁸ G¹ W² 2367 R¹⁰ G¹ W² 2368 R¹² G¹ W² 2369 R¹⁴ G¹ W² 2370 R¹⁵ G¹ W² 2371 R¹⁹ G¹ W² 2372 R²⁷ G¹ W² 2373 R²⁸ G¹ W² 2374 R³³ G¹ W² 2375 R³⁸ G¹ W² 2376 R³⁹ G¹ W² 2377 R⁴¹ G¹ W² 2378 R⁴⁶ G¹ W² 2379 R⁴⁷ G¹ W² 2380 R⁴⁹ G¹ W² 2381 R¹ G³ W² 2382 R² G³ W² 2383 R⁴ G³ W² 2384 R⁵ G³ W² 2385 R⁷ G³ W² 2386 R⁸ G³ W² 2387 R¹⁰ G³ W² 2388 R¹² G³ W² 2389 R¹⁴ G³ W² 2390 R¹⁵ G³ W² 2391 R¹⁹ G³ W² 2392 R²⁷ G³ W² 2393 R²⁸ G³ W² 2394 R³³ G³ W² 2395 R³⁸ G³ W² 2396 R³⁹ G³ W² 2397 R⁴¹ G³ W² 2398 R⁴⁶ G³ W² 2399 R⁴⁷ G³ W² 2400 R⁴⁹ G³ W² 2401 R¹ G⁵ W² 2402 R² G⁵ W² 2403 R⁴ G⁵ W² 2404 R⁵ G⁵ W² 2405 R⁷ G⁵ W² 2406 R⁸ G⁵ W² 2407 R¹⁰ G⁵ W² 2408 R¹² G⁵ W² 2409 R¹⁴ G⁵ W² 2410 R¹⁵ G⁵ W² 2411 R¹⁹ G⁵ W² 2412 R²⁷ G⁵ W² 2413 R²⁸ G⁵ W² 2414 R³³ G⁵ W² 2415 R³⁸ G⁵ W² 2416 R³⁹ G⁵ W² 2417 R⁴¹ G⁵ W² 2418 R⁴⁶ G⁵ W² 2419 R⁴⁷ G⁵ W² 2420 R⁴⁹ G⁵ W² 2421 R¹ G⁶ W² 2422 R² G⁶ W² 2423 R⁴ G⁶ W² 2424 R⁵ G⁶ W² 2425 R⁷ G⁶ W² 2426 R⁸ G⁶ W² 2427 R¹⁰ G⁶ W² 2428 R¹² G⁶ W² 2429 R¹⁴ G⁶ W² 2430 R¹⁵ G⁶ W² 2431 R¹⁹ G⁶ W² 2432 R²⁷ G⁶ W² 2433 R²⁸ G⁶ W² 2434 R³³ G⁶ W² 2435 R³⁸ G⁶ W² 2436 R³⁹ G⁶ W² 2437 R⁴¹ G⁶ W² 2438 R⁴⁶ G⁶ W² 2439 R⁴⁷ G⁶ W² 2440 R⁴⁹ G⁶ W² 2441 R¹ G⁹ W² 2442 R² G⁹ W² 2443 R⁴ G⁹ W² 2444 R⁵ G⁹ W² 2445 R⁷ G⁹ W² 2446 R⁸ G⁹ W² 2447 R¹⁰ G⁹ W² 2448 R¹² G⁹ W² 2449 R¹⁴ G⁹ W² 2450 R¹⁵ G⁹ W² 2451 R¹⁹ G⁹ W² 2452 R²⁷ G⁹ W² 2453 R²⁸ G⁹ W² 2454 R³³ G⁹ W² 2455 R³⁸ G⁹ W² 2456 R³⁹ G⁹ W² 2457 R⁴¹ G⁹ W² 2458 R⁴⁶ G⁹ W² 2459 R⁴⁷ G⁹ W² 2460 R⁴⁹ G⁹ W² 2461 R¹ G¹⁰ W² 2462 R² G¹⁰ W² 2463 R⁴ G¹⁰ W² 2464 R⁵ G¹⁰ W² 2465 R⁷ G¹⁰ W² 2466 R⁸ G¹⁰ W² 2467 R¹⁰ G¹⁰ W² 2468 R¹² G¹⁰ W² 2469 R¹⁴ G¹⁰ W² 2470 R¹⁵ G¹⁰ W² 2471 R¹⁹ G¹⁰ W² 2472 R²⁷ G¹⁰ W² 2473 R²⁸ G¹⁰ W² 2474 R³³ G¹⁰ W² 2475 R³⁸ G¹⁰ W² 2476 R³⁹ G¹⁰ W² 2477 R⁴¹ G¹⁰ W² 2478 R⁴⁶ G¹⁰ W² 2479 R⁴⁷ G¹⁰ W² 2480 R⁴⁹ G¹⁰ W² 2481 R¹ G²⁵ W² 2482 R² G²⁵ W² 2483 R⁴ G²⁵ W² 2484 R⁵ G²⁵ W² 2485 R⁷ G²⁵ W² 2486 R⁸ G²⁵ W² 2487 R¹⁰ G²⁵ W² 2488 R¹² G²⁵ W² 2489 R¹⁴ G²⁵ W² 2490 R¹⁵ G²⁵ W² 2491 R¹⁹ G²⁵ W² 2492 R²⁷ G²⁵ W² 2493 R²⁸ G²⁵ W² 2494 R³³ G²⁵ W² 2495 R³⁸ G²⁵ W² 2496 R³⁹ G²⁵ W² 2497 R⁴¹ G²⁵ W² 2498 R⁴⁶ G²⁵ W² 2499 R⁴⁷ G²⁵ W² 2500 R⁴⁹ G²⁵ W² 2501 R¹ G²⁶ W² 2502 R² G²⁶ W² 2503 R⁴ G²⁶ W² 2504 R⁵ G²⁶ W² 2505 R⁷ G²⁶ W² 2506 R⁸ G²⁶ W² 2507 R¹⁰ G²⁶ W² 2508 R¹² G²⁶ W² 2509 R¹⁴ G²⁶ W² 2510 R¹⁵ G²⁶ W² 2511 R¹⁹ G²⁶ W² 2512 R²⁷ G²⁶ W² 2513 R²⁸ G²⁶ W² 2514 R³³ G²⁶ W² 2515 R³⁸ G²⁶ W² 2516 R³⁹ G²⁶ W² 2517 R⁴¹ G²⁶ W² 2518 R⁴⁶ G²⁶ W² 2519 R⁴⁷ G²⁶ W² 2520 R⁴⁹ G²⁶ W² 2521 R¹ G²⁷ W² 2522 R² G²⁷ W² 2523 R⁴ G²⁷ W² 2524 R⁵ G²⁷ W² 2525 R⁷ G²⁷ W² 2526 R⁸ G²⁷ W² 2527 R¹⁰ G²⁷ W² 2528 R¹² G²⁷ W² 2529 R¹⁴ G²⁷ W² 2530 R¹⁵ G²⁷ W² 2531 R¹⁹ G²⁷ W² 2532 R²⁷ G²⁷ W² 2533 R²⁸ G²⁷ W² 2534 R³³ G²⁷ W² 2535 R³⁸ G²⁷ W² 2536 R³⁹ G²⁷ W² 2537 R⁴¹ G²⁷ W² 2538 R⁴⁶ G²⁷ W² 2539 R⁴⁷ G²⁷ W² 2540 R⁴⁹ G²⁷ W² 2541 R¹ G²⁸ W² 2542 R² G²⁸ W² 2543 R⁴ G²⁸ W² 2544 R⁵ G²⁸ W² 2545 R⁷ G²⁸ W² 2546 R⁸ G²⁸ W² 2547 R¹⁰ G²⁸ W² 2548 R¹² G²⁸ W² 2549 R¹⁴ G²⁸ W² 2550 R¹⁵ G²⁸ W² 2551 R¹⁹ G²⁸ W² 2552 R²⁷ G²⁸ W² 2553 R²⁸ G²⁸ W² 2554 R³³ G²⁸ W² 2555 R³⁸ G²⁸ W² 2556 R³⁹ G²⁸ W² 2557 R⁴¹ G²⁸ W² 2558 R⁴⁶ G²⁸ W² 2559 R⁴⁷ G²⁸ W² 2560 R⁴⁹ G²⁸ W² 2561 R¹ G¹ W⁵ 2562 R² G¹ W⁵ 2563 R⁴ G¹ W⁵ 2564 R⁵ G¹ W⁵ 2565 R⁷ G¹ W⁵ 2566 R⁸ G¹ W⁵ 2567 R¹⁰ G¹ W⁵ 2568 R¹² G¹ W⁵ 2569 R¹⁴ G¹ W⁵ 2570 R¹⁵ G¹ W⁵ 2571 R¹⁹ G¹ W⁵ 2572 R²⁷ G¹ W⁵ 2573 R²⁸ G¹ W⁵ 2574 R³³ G¹ W⁵ 2575 R³⁸ G¹ W⁵ 2576 R³⁹ G¹ W⁵ 2577 R⁴¹ G¹ W⁵ 2578 R⁴⁶ G¹ W⁵ 2579 R⁴⁷ G¹ W⁵ 2580 R⁴⁹ G¹ W⁵ 2581 R¹ G³ W⁵ 2582 R² G³ W⁵ 2583 R⁴ G³ W⁵ 2584 R⁵ G³ W⁵ 2585 R⁷ G³ W⁵ 2586 R⁸ G³ W⁵ 2587 R¹⁰ G³ W⁵ 2588 R¹² G³ W⁵ 2589 R¹⁴ G³ W⁵ 2590 R¹⁵ G³ W⁵ 2591 R¹⁹ G³ W⁵ 2592 R²⁷ G³ W⁵ 2593 R²⁸ G³ W⁵ 2594 R³³ G³ W⁵ 2595 R³⁸ G³ W⁵ 2596 R³⁹ G³ W⁵ 2597 R⁴¹ G³ W⁵ 2598 R⁴⁶ G³ W⁵ 2599 R⁴⁷ G³ W⁵ 2600 R⁴⁹ G³ W⁵ 2601 R¹ G⁵ W⁵ 2602 R² G⁵ W⁵ 2603 R⁴ G⁵ W⁵ 2604 R⁵ G⁵ W⁵ 2605 R⁷ G⁵ W⁵ 2606 R⁸ G⁵ W⁵ 2607 R¹⁰ G⁵ W⁵ 2608 R¹² G⁵ W⁵ 2609 R¹⁴ G⁵ W⁵ 2610 R¹⁵ G⁵ W⁵ 2611 R¹⁹ G⁵ W⁵ 2612 R²⁷ G⁵ W⁵ 2613 R²⁸ G⁵ W⁵ 2614 R³³ G⁵ W⁵ 2615 R³⁸ G⁵ W⁵ 2616 R³⁹ G⁵ W⁵ 2617 R⁴¹ G⁵ W⁵ 2618 R⁴⁶ G⁵ W⁵ 2619 R⁴⁷ G⁵ W⁵ 2620 R⁴⁹ G⁵ W⁵ 2621 R¹ G⁶ W⁵ 2622 R² G⁶ W⁵ 2623 R⁴ G⁶ W⁵ 2624 R⁵ G⁶ W⁵ 2625 R⁷ G⁶ W⁵ 2626 R⁸ G⁶ W⁵ 2627 R¹⁰ G⁶ W⁵ 2628 R¹² G⁶ W⁵ 2629 R¹⁴ G⁶ W⁵ 2630 R¹⁵ G⁶ W⁵ 2631 R¹⁹ G⁶ W⁵ 2632 R²⁷ G⁶ W⁵ 2633 R²⁸ G⁶ W⁵ 2634 R³³ G⁶ W⁵ 2635 R³⁸ G⁶ W⁵ 2636 R³⁹ G⁶ W⁵ 2637 R⁴¹ G⁶ W⁵ 2638 R⁴⁶ G⁶ W⁵ 2639 R⁴⁷ G⁶ W⁵ 2640 R⁴⁹ G⁶ W⁵ 2641 R¹ G⁹ W⁵ 2642 R² G⁹ W⁵ 2643 R⁴ G⁹ W⁵ 2644 R⁵ G⁹ W⁵ 2645 R⁷ G⁹ W⁵ 2646 R⁸ G⁹ W⁵ 2647 R¹⁰ G⁹ W⁵ 2648 R¹² G⁹ W⁵ 2649 R¹⁴ G⁹ W⁵ 2650 R¹⁵ G⁹ W⁵ 2651 R¹⁹ G⁹ W⁵ 2652 R²⁷ G⁹ W⁵ 2653 R²⁸ G⁹ W⁵ 2654 R³³ G⁹ W⁵ 2655 R³⁸ G⁹ W⁵ 2656 R³⁹ G⁹ W⁵ 2657 R⁴¹ G⁹ W⁵ 2658 R⁴⁶ G⁹ W⁵ 2659 R⁴⁷ G⁹ W⁵ 2660 R⁴⁹ G⁹ W⁵ 2661 R¹ G¹⁰ W⁵ 2662 R² G¹⁰ W⁵ 2663 R⁴ G¹⁰ W⁵ 2664 R⁵ G¹⁰ W⁵ 2665 R⁷ G¹⁰ W⁵ 2666 R⁸ G¹⁰ W⁵ 2667 R¹⁰ G¹⁰ W⁵ 2668 R¹² G¹⁰ W⁵ 2669 R¹⁴ G¹⁰ W⁵ 2670 R¹⁵ G¹⁰ W⁵ 2671 R¹⁹ G¹⁰ W⁵ 2672 R²⁷ G¹⁰ W⁵ 2673 R²⁸ G¹⁰ W⁵ 2674 R³³ G¹⁰ W⁵ 2675 R³⁸ G¹⁰ W⁵ 2676 R³⁹ G¹⁰ W⁵ 2677 R⁴¹ G¹⁰ W⁵ 2678 R⁴⁶ G¹⁰ W⁵ 2679 R⁴⁷ G¹⁰ W⁵ 2680 R⁴⁹ G¹⁰ W⁵ 2681 R¹ G²⁵ W⁵ 2682 R² G²⁵ W⁵ 2683 R⁴ G²⁵ W⁵ 2684 R⁵ G²⁵ W⁵ 2685 R⁷ G²⁵ W⁵ 2686 R⁸ G²⁵ W⁵ 2687 R¹⁰ G²⁵ W⁵ 2688 R¹² G²⁵ W⁵ 2689 R¹⁴ G²⁵ W⁵ 2690 R¹⁵ G²⁵ W⁵ 2691 R¹⁹ G²⁵ W⁵ 2692 R²⁷ G²⁵ W⁵ 2693 R²⁸ G²⁵ W⁵ 2694 R³³ G²⁵ W⁵ 2695 R³⁸ G²⁵ W⁵ 2696 R³⁹ G²⁵ W⁵ 2697 R⁴¹ G²⁵ W⁵ 2698 R⁴⁶ G²⁵ W⁵ 2699 R⁴⁷ G²⁵ W⁵ 2700 R⁴⁹ G²⁵ W⁵ 2701 R¹ G²⁶ W⁵ 2702 R² G²⁶ W⁵ 2703 R⁴ G²⁶ W⁵ 2704 R⁵ G²⁶ W⁵ 2705 R⁷ G²⁶ W⁵ 2706 R⁸ G²⁶ W⁵ 2707 R¹⁰ G²⁶ W⁵ 2708 R¹² G²⁶ W⁵ 2709 R¹⁴ G²⁶ W⁵ 2710 R¹⁵ G²⁶ W⁵ 2711 R¹⁹ G²⁶ W⁵ 2712 R²⁷ G²⁶ W⁵ 2713 R²⁸ G²⁶ W⁵ 2714 R³³ G²⁶ W⁵ 2715 R³⁸ G²⁶ W⁵ 2716 R³⁹ G²⁶ W⁵ 2717 R⁴¹ G²⁶ W⁵ 2718 R⁴⁶ G²⁶ W⁵ 2719 R⁴⁷ G²⁶ W⁵ 2720 R⁴⁹ G²⁶ W⁵ 2721 R¹ G²⁷ W⁵ 2722 R² G²⁷ W⁵ 2723 R⁴ G²⁷ W⁵ 2724 R⁵ G²⁷ W⁵ 2725 R⁷ G²⁷ W⁵ 2726 R⁸ G²⁷ W⁵ 2727 R¹⁰ G²⁷ W⁵ 2728 R¹² G²⁷ W⁵ 2729 R¹⁴ G²⁷ W⁵ 2730 R¹⁵ G²⁷ W⁵ 2731 R¹⁹ G²⁷ W⁵ 2732 R²⁷ G²⁷ W⁵ 2733 R²⁸ G²⁷ W⁵ 2734 R³³ G²⁷ W⁵ 2735 R³⁸ G²⁷ W⁵ 2736 R³⁹ G²⁷ W⁵ 2737 R⁴¹ G²⁷ W⁵ 2738 R⁴⁶ G²⁷ W⁵ 2739 R⁴⁷ G²⁷ W⁵ 2740 R⁴⁹ G²⁷ W⁵ 2741 R¹ G²⁸ W⁵ 2742 R² G²⁸ W⁵ 2743 R⁴ G²⁸ W⁵ 2744 R⁵ G²⁸ W⁵ 2745 R⁷ G²⁸ W⁵ 2746 R⁸ G²⁸ W⁵ 2747 R¹⁰ G²⁸ W⁵ 2748 R¹² G²⁸ W⁵ 2749 R¹⁴ G²⁸ W⁵ 2750 R¹⁵ G²⁸ W⁵ 2751 R¹⁹ G²⁸ W⁵ 2752 R²⁷ G²⁸ W⁵ 2753 R²⁸ G²⁸ W⁵ 2754 R³³ G²⁸ W⁵ 2755 R³⁸ G²⁸ W⁵ 2756 R³⁹ G²⁸ W⁵ 2757 R⁴¹ G²⁸ W⁵ 2758 R⁴⁶ G²⁸ W⁵ 2759 R⁴⁷ G²⁸ W⁵ 2760 R⁴⁹ G²⁸ W⁵ 2761 R¹ G¹ W⁶ 2762 R² G¹ W⁶ 2763 R⁴ G¹ W⁶ 2764 R⁵ G¹ W⁶ 2765 R⁷ G¹ W⁶ 2766 R⁸ G¹ W⁶ 2767 R¹⁰ G¹ W⁶ 2768 R¹² G¹ W⁶ 2769 R¹⁴ G¹ W⁶ 2770 R¹⁵ G¹ W⁶ 2771 R¹⁹ G¹ W⁶ 2772 R²⁷ G¹ W⁶ 2773 R²⁸ G¹ W⁶ 2774 R³³ G¹ W⁶ 2775 R³⁸ G¹ W⁶ 2776 R³⁹ G¹ W⁶ 2777 R⁴¹ G¹ W⁶ 2778 R⁴⁶ G¹ W⁶ 2779 R⁴⁷ G¹ W⁶ 2780 R⁴⁹ G¹ W⁶ 2781 R¹ G³ W⁶ 2782 R² G³ W⁶ 2783 R⁴ G³ W⁶ 2784 R⁵ G³ W⁶ 2785 R⁷ G³ W⁶ 2786 R⁸ G³ W⁶ 2787 R¹⁰ G³ W⁶ 2788 R¹² G³ W⁶ 2789 R¹⁴ G³ W⁶ 2790 R¹⁵ G³ W⁶ 2791 R¹⁹ G³ W⁶ 2792 R²⁷ G³ W⁶ 2793 R²⁸ G³ W⁶ 2794 R³³ G³ W⁶ 2795 R³⁸ G³ W⁶ 2796 R³⁹ G³ W⁶ 2797 R⁴¹ G³ W⁶ 2798 R⁴⁶ G³ W⁶ 2799 R⁴⁷ G³ W⁶ 2800 R⁴⁹ G³ W⁶ 2801 R¹ G⁵ W⁶ 2802 R² G⁵ W⁶ 2803 R⁴ G⁵ W⁶ 2804 R⁵ G⁵ W⁶ 2805 R⁷ G⁵ W⁶ 2806 R⁸ G⁵ W⁶ 2807 R¹⁰ G⁵ W⁶ 2808 R¹² G⁵ W⁶ 2809 R¹⁴ G⁵ W⁶ 2810 R¹⁵ G⁵ W⁶ 2811 R¹⁹ G⁵ W⁶ 2812 R²⁷ G⁵ W⁶ 2813 R²⁸ G⁵ W⁶ 2814 R³³ G⁵ W⁶ 2815 R³⁸ G⁵ W⁶ 2816 R³⁹ G⁵ W⁶ 2817 R⁴¹ G⁵ W⁶ 2818 R⁴⁶ G⁵ W⁶ 2819 R⁴⁷ G⁵ W⁶ 2820 R⁴⁹ G⁵ W⁶ 2821 R¹ G⁶ W⁶ 2822 R² G⁶ W⁶ 2823 R⁴ G⁶ W⁶ 2824 R⁵ G⁶ W⁶ 2825 R⁷ G⁶ W⁶ 2826 R⁸ G⁶ W⁶ 2827 R¹⁰ G⁶ W⁶ 2828 R¹² G⁶ W⁶ 2829 R¹⁴ G⁶ W⁶ 2830 R¹⁵ G⁶ W⁶ 2831 R¹⁹ G⁶ W⁶ 2832 R²⁷ G⁶ W⁶ 2833 R²⁸ G⁶ W⁶ 2834 R³³ G⁶ W⁶ 2835 R³⁸ G⁶ W⁶ 2836 R³⁹ G⁶ W⁶ 2837 R⁴¹ G⁶ W⁶ 2838 R⁴⁶ G⁶ W⁶ 2839 R⁴⁷ G⁶ W⁶ 2840 R⁴⁹ G⁶ W⁶ 2841 R¹ G⁹ W⁶ 2842 R² G⁹ W⁶ 2843 R⁴ G⁹ W⁶ 2844 R⁵ G⁹ W⁶ 2845 R⁷ G⁹ W⁶ 2846 R⁸ G⁹ W⁶ 2847 R¹⁰ G⁹ W⁶ 2848 R¹² G⁹ W⁶ 2849 R¹⁴ G⁹ W⁶ 2850 R¹⁵ G⁹ W⁶ 2851 R¹⁹ G⁹ W⁶ 2852 R²⁷ G⁹ W⁶ 2853 R²⁸ G⁹ W⁶ 2854 R³³ G⁹ W⁶ 2855 R³⁸ G⁹ W⁶ 2856 R³⁹ G⁹ W⁶ 2857 R⁴¹ G⁹ W⁶ 2858 R⁴⁶ G⁹ W⁶ 2859 R⁴⁷ G⁹ W⁶ 2860 R⁴⁹ G⁹ W⁶ 2861 R¹ G¹⁰ W⁶ 2862 R² G¹⁰ W⁶ 2863 R⁴ G¹⁰ W⁶ 2864 R⁵ G¹⁰ W⁶ 2865 R⁷ G¹⁰ W⁶ 2866 R⁸ G¹⁰ W⁶ 2867 R¹⁰ G¹⁰ W⁶ 2868 R¹² G¹⁰ W⁶ 2869 R¹⁴ G¹⁰ W⁶ 2870 R¹⁵ G¹⁰ W⁶ 2871 R¹⁹ G¹⁰ W⁶ 2872 R²⁷ G¹⁰ W⁶ 2873 R²⁸ G¹⁰ W⁶ 2874 R³³ G¹⁰ W⁶ 2875 R³⁸ G¹⁰ W⁶ 2876 R³⁹ G¹⁰ W⁶ 2877 R⁴¹ G¹⁰ W⁶ 2878 R⁴⁶ G¹⁰ W⁶ 2879 R⁴⁷ G¹⁰ W⁶ 2880 R⁴⁹ G¹⁰ W⁶ 2881 R¹ G²⁵ W⁶ 2882 R² G²⁵ W⁶ 2883 R⁴ G²⁵ W⁶ 2884 R⁵ G²⁵ W⁶ 2885 R⁷ G²⁵ W⁶ 2886 R⁸ G²⁵ W⁶ 2887 R¹⁰ G²⁵ W⁶ 2888 R¹² G²⁵ W⁶ 2889 R¹⁴ G²⁵ W⁶ 2890 R¹⁵ G²⁵ W⁶ 2891 R¹⁹ G²⁵ W⁶ 2892 R²⁷ G²⁵ W⁶ 2893 R²⁸ G²⁵ W⁶ 2894 R³³ G²⁵ W⁶ 2895 R³⁸ G²⁵ W⁶ 2896 R³⁹ G²⁵ W⁶ 2897 R⁴¹ G²⁵ W⁶ 2898 R⁴⁶ G²⁵ W⁶ 2899 R⁴⁷ G²⁵ W⁶ 2900 R⁴⁹ G²⁵ W⁶ 2901 R¹ G²⁶ W⁶ 2902 R² G²⁶ W⁶ 2903 R⁴ G²⁶ W⁶ 2904 R⁵ G²⁶ W⁶ 2905 R⁷ G²⁶ W⁶ 2906 R⁸ G²⁶ W⁶ 2907 R¹⁰ G²⁶ W⁶ 2908 R¹² G²⁶ W⁶ 2909 R¹⁴ G²⁶ W⁶ 2910 R¹⁵ G²⁶ W⁶ 2911 R¹⁹ G²⁶ W⁶ 2912 R²⁷ G²⁶ W⁶ 2913 R²⁸ G²⁶ W⁶ 2914 R³³ G²⁶ W⁶ 2915 R³⁸ G²⁶ W⁶ 2916 R³⁹ G²⁶ W⁶ 2917 R⁴¹ G²⁶ W⁶ 2918 R⁴⁶ G²⁶ W⁶ 2919 R⁴⁷ G²⁶ W⁶ 2920 R⁴⁹ G²⁶ W⁶ 2921 R¹ G²⁷ W⁶ 2922 R² G²⁷ W⁶ 2923 R⁴ G²⁷ W⁶ 2924 R⁵ G²⁷ W⁶ 2925 R⁷ G²⁷ W⁶ 2926 R⁸ G²⁷ W⁶ 2927 R¹⁰ G²⁷ W⁶ 2928 R¹² G²⁷ W⁶ 2929 R¹⁴ G²⁷ W⁶ 2930 R¹⁵ G²⁷ W⁶ 2931 R¹⁹ G²⁷ W⁶ 2932 R²⁷ G²⁷ W⁶ 2933 R²⁸ G²⁷ W⁶ 2934 R³³ G²⁷ W⁶ 2935 R³⁸ G²⁷ W⁶ 2936 R³⁹ G²⁷ W⁶ 2937 R⁴¹ G²⁷ W⁶ 2938 R⁴⁶ G²⁷ W⁶ 2939 R⁴⁷ G²⁷ W⁶ 2940 R⁴⁹ G²⁷ W⁶ 2941 R¹ G²⁸ W⁶ 2942 R² G²⁸ W⁶ 2943 R⁴ G²⁸ W⁶ 2944 R⁵ G²⁸ W⁶ 2945 R⁷ G²⁸ W⁶ 2946 R⁸ G²⁸ W⁶ 2947 R¹⁰ G²⁸ W⁶ 2948 R¹² G²⁸ W⁶ 2949 R¹⁴ G²⁸ W⁶ 2950 R¹⁵ G²⁸ W⁶ 2951 R¹⁹ G²⁸ W⁶ 2952 R²⁷ G²⁸ W⁶ 2953 R²⁸ G²⁸ W⁶ 2954 R³³ G²⁸ W⁶ 2955 R³⁸ G²⁸ W⁶ 2956 R³⁹ G²⁸ W⁶ 2957 R⁴¹ G²⁸ W⁶ 2958 R⁴⁶ G²⁸ W⁶ 2959 R⁴⁷ G²⁸ W⁶ 2960 R⁴⁹ G²⁸ W⁶ 2961 R¹ G¹ W¹¹ 2962 R² G¹ W¹¹ 2963 R⁴ G¹ W¹¹ 2964 R⁵ G¹ W¹¹ 2965 R⁷ G¹ W¹¹ 2966 R⁸ G¹ W¹¹ 2967 R¹⁰ G¹ W¹¹ 2968 R¹² G¹ W¹¹ 2969 R¹⁴ G¹ W¹¹ 2970 R¹⁵ G¹ W¹¹ 2971 R¹⁹ G¹ W¹¹ 2972 R²⁷ G¹ W¹¹ 2973 R²⁸ G¹ W¹¹ 2974 R³³ G¹ W¹¹ 2975 R³⁸ G¹ W¹¹ 2976 R³⁹ G¹ W¹¹ 2977 R⁴¹ G¹ W¹¹ 2978 R⁴⁶ G¹ W¹¹ 2979 R⁴⁷ G¹ W¹¹ 2980 R⁴⁹ G¹ W¹¹ 2981 R¹ G³ W¹¹ 2982 R² G³ W¹¹ 2983 R⁴ G³ W¹¹ 2984 R⁵ G³ W¹¹ 2985 R⁷ G³ W¹¹ 2986 R⁸ G³ W¹¹ 2987 R¹⁰ G³ W¹¹ 2988 R¹² G³ W¹¹ 2989 R¹⁴ G³ W¹¹ 2990 R¹⁵ G³ W¹¹ 2991 R¹⁹ G³ W¹¹ 2992 R²⁷ G³ W¹¹ 2993 R²⁸ G³ W¹¹ 2994 R³³ G³ W¹¹ 2995 R³⁸ G³ W¹¹ 2996 R³⁹ G³ W¹¹ 2997 R⁴¹ G³ W¹¹ 2998 R⁴⁶ G³ W¹¹ 2999 R⁴⁷ G³ W¹¹ 3000 R⁴⁹ G³ W¹¹ 3001 R¹ G⁵ W¹¹ 3002 R² G⁵ W¹¹ 3003 R⁴ G⁵ W¹¹ 3004 R⁵ G⁵ W¹¹ 3005 R⁷ G⁵ W¹¹ 3006 R⁸ G⁵ W¹¹ 3007 R¹⁰ G⁵ W¹¹ 3008 R¹² G⁵ W¹¹ 3009 R¹⁴ G⁵ W¹¹ 3010 R¹⁵ G⁵ W¹¹ 3011 R¹⁹ G⁵ W¹¹ 3012 R²⁷ G⁵ W¹¹ 3013 R²⁸ G⁵ W¹¹ 3014 R³³ G⁵ W¹¹ 3015 R³⁸ G⁵ W¹¹ 3016 R³⁹ G⁵ W¹¹ 3017 R⁴¹ G⁵ W¹¹ 3018 R⁴⁶ G⁵ W¹¹ 3019 R⁴⁷ G⁵ W¹¹ 3020 R⁴⁹ G⁵ W¹¹ 3021 R¹ G⁶ W¹¹ 3022 R² G⁶ W¹¹ 3023 R⁴ G⁶ W¹¹ 3024 R⁵ G⁶ W¹¹ 3025 R⁷ G⁶ W¹¹ 3026 R⁸ G⁶ W¹¹ 3027 R¹⁰ G⁶ W¹¹ 3028 R¹² G⁶ W¹¹ 3029 R¹⁴ G⁶ W¹¹ 3030 R¹⁵ G⁶ W¹¹ 3031 R¹⁹ G⁶ W¹¹ 3032 R²⁷ G⁶ W¹¹ 3033 R²⁸ G⁶ W¹¹ 3034 R³³ G⁶ W¹¹ 3035 R³⁸ G⁶ W¹¹ 3036 R³⁹ G⁶ W¹¹ 3037 R⁴¹ G⁶ W¹¹ 3038 R⁴⁶ G⁶ W¹¹ 3039 R⁴⁷ G⁶ W¹¹ 3040 R⁴⁹ G⁶ W¹¹ 3041 R¹ G⁹ W¹¹ 3042 R² G⁹ W¹¹ 3043 R⁴ G⁹ W¹¹ 3044 R⁵ G⁹ W¹¹ 3045 R⁷ G⁹ W¹¹ 3046 R⁸ G⁹ W¹¹ 3047 R¹⁰ G⁹ W¹¹ 3048 R¹² G⁹ W¹¹ 3049 R¹⁴ G⁹ W¹¹ 3050 R¹⁵ G⁹ W¹¹ 3051 R¹⁹ G⁹ W¹¹ 3052 R²⁷ G⁹ W¹¹ 3053 R²⁸ G⁹ W¹¹ 3054 R³³ G⁹ W¹¹ 3055 R³⁸ G⁹ W¹¹ 3056 R³⁹ G⁹ W¹¹ 3057 R⁴¹ G⁹ W¹¹ 3058 R⁴⁶ G⁹ W¹¹ 3059 R⁴⁷ G⁹ W¹¹ 3060 R⁴⁹ G⁹ W¹¹ 3061 R¹ G¹⁰ W¹¹ 3062 R² G¹⁰ W¹¹ 3063 R⁴ G¹⁰ W¹¹ 3064 R⁵ G¹⁰ W¹¹ 3065 R⁷ G¹⁰ W¹¹ 3066 R⁸ G¹⁰ W¹¹ 3067 R¹⁰ G¹⁰ W¹¹ 3068 R¹² G¹⁰ W¹¹ 3069 R¹⁴ G¹⁰ W¹¹ 3070 R¹⁵ G¹⁰ W¹¹ 3071 R¹⁹ G¹⁰ W¹¹ 3072 R²⁷ G¹⁰ W¹¹ 3073 R²⁸ G¹⁰ W¹¹ 3074 R³³ G¹⁰ W¹¹ 3075 R³⁸ G¹⁰ W¹¹ 3076 R³⁹ G¹⁰ W¹¹ 3077 R⁴¹ G¹⁰ W¹¹ 3078 R⁴⁶ G¹⁰ W¹¹ 3079 R⁴⁷ G¹⁰ W¹¹ 3080 R⁴⁹ G¹⁰ W¹¹ 3081 R¹ G²⁵ W¹¹ 3082 R² G²⁵ W¹¹ 3083 R⁴ G²⁵ W¹¹ 3084 R⁵ G²⁵ W¹¹ 3085 R⁷ G²⁵ W¹¹ 3086 R⁸ G²⁵ W¹¹ 3087 R¹⁰ G²⁵ W¹¹ 3088 R¹² G²⁵ W¹¹ 3089 R¹⁴ G²⁵ W¹¹ 3090 R¹⁵ G²⁵ W¹¹ 3091 R¹⁹ G²⁵ W¹¹ 3092 R²⁷ G²⁵ W¹¹ 3093 R²⁸ G²⁵ W¹¹ 3094 R³³ G²⁵ W¹¹ 3095 R³⁸ G²⁵ W¹¹ 3096 R³⁹ G²⁵ W¹¹ 3097 R⁴¹ G²⁵ W¹¹ 3098 R⁴⁶ G²⁵ W¹¹ 3099 R⁴⁷ G²⁵ W¹¹ 3100 R⁴⁹ G²⁵ W¹¹ 3101 R¹ G²⁶ W¹¹ 3102 R² G²⁶ W¹¹ 3103 R⁴ G²⁶ W¹¹ 3104 R⁵ G²⁶ W¹¹ 3105 R⁷ G²⁶ W¹¹ 3106 R⁸ G²⁶ W¹¹ 3107 R¹⁰ G²⁶ W¹¹ 3108 R¹² G²⁶ W¹¹ 3109 R¹⁴ G²⁶ W¹¹ 3110 R¹⁵ G²⁶ W¹¹ 3111 R¹⁹ G²⁶ W¹¹ 3112 R²⁷ G²⁶ W¹¹ 3113 R²⁸ G²⁶ W¹¹ 3114 R³³ G²⁶ W¹¹ 3115 R³⁸ G²⁶ W¹¹ 3116 R³⁹ G²⁶ W¹¹ 3117 R⁴¹ G²⁶ W¹¹ 3118 R⁴⁶ G²⁶ W¹¹ 3119 R⁴⁷ G²⁶ W¹¹ 3120 R⁴⁹ G²⁶ W¹¹ 3121 R¹ G²⁷ W¹¹ 3122 R² G²⁷ W¹¹ 3123 R⁴ G²⁷ W¹¹ 3124 R⁵ G²⁷ W¹¹ 3125 R⁷ G²⁷ W¹¹ 3126 R⁸ G²⁷ W¹¹ 3127 R¹⁰ G²⁷ W¹¹ 3128 R¹² G²⁷ W¹¹ 3129 R¹⁴ G²⁷ W¹¹ 3130 R¹⁵ G²⁷ W¹¹ 3131 R¹⁹ G²⁷ W¹¹ 3132 R²⁷ G²⁷ W¹¹ 3133 R²⁸ G²⁷ W¹¹ 3134 R³³ G²⁷ W¹¹ 3135 R³⁸ G²⁷ W¹¹ 3136 R³⁹ G²⁷ W¹¹ 3137 R⁴¹ G²⁷ W¹¹ 3138 R⁴⁶ G²⁷ W¹¹ 3139 R⁴⁷ G²⁷ W¹¹ 3140 R⁴⁹ G²⁷ W¹¹ 3141 R¹ G²⁸ W¹¹ 3142 R² G²⁸ W¹¹ 3143 R⁴ G²⁸ W¹¹ 3144 R⁵ G²⁸ W¹¹ 3145 R⁷ G²⁸ W¹¹ 3146 R⁸ G²⁸ W¹¹ 3147 R¹⁰ G²⁸ W¹¹ 3148 R¹² G²⁸ W¹¹ 3149 R¹⁴ G²⁸ W¹¹ 3150 R¹⁵ G²⁸ W¹¹ 3151 R¹⁹ G²⁸ W¹¹ 3152 R²⁷ G²⁸ W¹¹ 3153 R²⁸ G²⁸ W¹¹ 3154 R³³ G²⁸ W¹¹ 3155 R³⁸ G²⁸ W¹¹ 3156 R³⁹ G²⁸ W¹¹ 3157 R⁴¹ G²⁸ W¹¹ 3158 R⁴⁶ G²⁸ W¹¹ 3159 R⁴⁷ G²⁸ W¹¹ 3160 R⁴⁹ G²⁸ W¹¹ 3161 R¹ G¹ W¹⁷ 3162 R² G¹ W¹⁷ 3163 R⁴ G¹ W¹⁷ 3164 R⁵ G¹ W¹⁷ 3165 R⁷ G¹ W¹⁷ 3166 R⁸ G¹ W¹⁷ 3167 R¹⁰ G¹ W¹⁷ 3168 R¹² G¹ W¹⁷ 3169 R¹⁴ G¹ W¹⁷ 3170 R¹⁵ G¹ W¹⁷ 3171 R¹⁹ G¹ W¹⁷ 3172 R²⁷ G¹ W¹⁷ 3173 R²⁸ G¹ W¹⁷ 3174 R³³ G¹ W¹⁷ 3175 R³⁸ G¹ W¹⁷ 3176 R³⁹ G¹ W¹⁷ 3177 R⁴¹ G¹ W¹⁷ 3178 R⁴⁶ G¹ W¹⁷ 3179 R⁴⁷ G¹ W¹⁷ 3180 R⁴⁹ G¹ W¹⁷ 3181 R¹ G³ W¹⁷ 3182 R² G³ W¹⁷ 3183 R⁴ G³ W¹⁷ 3184 R⁵ G³ W¹⁷ 3185 R⁷ G³ W¹⁷ 3186 R⁸ G³ W¹⁷ 3187 R¹⁰ G³ W¹⁷ 3188 R¹² G³ W¹⁷ 3189 R¹⁴ G³ W¹⁷ 3190 R¹⁵ G³ W¹⁷ 3191 R¹⁹ G³ W¹⁷ 3192 R²⁷ G³ W¹⁷ 3193 R²⁸ G³ W¹⁷ 3194 R³³ G³ W¹⁷ 3195 R³⁸ G³ W¹⁷ 3196 R³⁹ G³ W¹⁷ 3197 R⁴¹ G³ W¹⁷ 3198 R⁴⁶ G³ W¹⁷ 3199 R⁴⁷ G³ W¹⁷ 3200 R⁴⁹ G³ W¹⁷ 3201 R¹ G⁵ W¹⁷ 3202 R² G⁵ W¹⁷ 3203 R⁴ G⁵ W¹⁷ 3204 R⁵ G⁵ W¹⁷ 3205 R⁷ G⁵ W¹⁷ 3206 R⁸ G⁵ W¹⁷ 3207 R¹⁰ G⁵ W¹⁷ 3208 R¹² G⁵ W¹⁷ 3209 R¹⁴ G⁵ W¹⁷ 3210 R¹⁵ G⁵ W¹⁷ 3211 R¹⁹ G⁵ W¹⁷ 3212 R²⁷ G⁵ W¹⁷ 3213 R²⁸ G⁵ W¹⁷ 3214 R³³ G⁵ W¹⁷ 3215 R³⁸ G⁵ W¹⁷ 3216 R³⁹ G⁵ W¹⁷ 3217 R⁴¹ G⁵ W¹⁷ 3218 R⁴⁶ G⁵ W¹⁷ 3219 R⁴⁷ G⁵ W¹⁷ 3220 R⁴⁹ G⁵ W¹⁷ 3221 R¹ G⁶ W¹⁷ 3222 R² G⁶ W¹⁷ 3223 R⁴ G⁶ W¹⁷ 3224 R⁵ G⁶ W¹⁷ 3225 R⁷ G⁶ W¹⁷ 3226 R⁸ G⁶ W¹⁷ 3227 R¹⁰ G⁶ W¹⁷ 3228 R¹² G⁶ W¹⁷ 3229 R¹⁴ G⁶ W¹⁷ 3230 R¹⁵ G⁶ W¹⁷ 3231 R¹⁹ G⁶ W¹⁷ 3232 R²⁷ G⁶ W¹⁷ 3233 R²⁸ G⁶ W¹⁷ 3234 R³³ G⁶ W¹⁷ 3235 R³⁸ G⁶ W¹⁷ 3236 R³⁹ G⁶ W¹⁷ 3237 R⁴¹ G⁶ W¹⁷ 3238 R⁴⁶ G⁶ W¹⁷ 3239 R⁴⁷ G⁶ W¹⁷ 3240 R⁴⁹ G⁶ W¹⁷ 3241 R¹ G⁹ W¹⁷ 3242 R² G⁹ W¹⁷ 3243 R⁴ G⁹ W¹⁷ 3244 R⁵ G⁹ W¹⁷ 3245 R⁷ G⁹ W¹⁷ 3246 R⁸ G⁹ W¹⁷ 3247 R¹⁰ G⁹ W¹⁷ 3248 R¹² G⁹ W¹⁷ 3249 R¹⁴ G⁹ W¹⁷ 3250 R¹⁵ G⁹ W¹⁷ 3251 R¹⁹ G⁹ W¹⁷ 3252 R²⁷ G⁹ W¹⁷ 3253 R²⁸ G⁹ W¹⁷ 3254 R³³ G⁹ W¹⁷ 3255 R³⁸ 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G⁶ W²⁸ 3625 R⁷ G⁶ W²⁸ 3626 R⁸ G⁶ W²⁸ 3627 R¹⁰ G⁶ W²⁸ 3628 R¹² G⁶ W²⁸ 3629 R¹⁴ G⁶ W²⁸ 3630 R¹⁵ G⁶ W²⁸ 3631 R¹⁹ G⁶ W²⁸ 3632 R²⁷ G⁶ W²⁸ 3633 R²⁸ G⁶ W²⁸ 3634 R³³ G⁶ W²⁸ 3635 R³⁸ G⁶ W²⁸ 3636 R³⁹ G⁶ W²⁸ 3637 R⁴¹ G⁶ W²⁸ 3638 R⁴⁶ G⁶ W²⁸ 3639 R⁴⁷ G⁶ W²⁸ 3640 R⁴⁹ G⁶ W²⁸ 3641 R¹ G⁹ W²⁸ 3642 R² G⁹ W²⁸ 3643 R⁴ G⁹ W²⁸ 3644 R⁵ G⁹ W²⁸ 3645 R⁷ G⁹ W²⁸ 3646 R⁸ G⁹ W²⁸ 3647 R¹⁰ G⁹ W²⁸ 3648 R¹² G⁹ W²⁸ 3649 R¹⁴ G⁹ W²⁸ 3650 R¹⁵ G⁹ W²⁸ 3651 R¹⁹ G⁹ W²⁸ 3652 R²⁷ G⁹ W²⁸ 3653 R²⁸ G⁹ W²⁸ 3654 R³³ G⁹ W²⁸ 3655 R³⁸ G⁹ W²⁸ 3656 R³⁹ G⁹ W²⁸ 3657 R⁴¹ G⁹ W²⁸ 3658 R⁴⁶ G⁹ W²⁸ 3659 R⁴⁷ G⁹ W²⁸ 3660 R⁴⁹ G⁹ W²⁸ 3661 R¹ G¹⁰ W²⁸ 3662 R² G¹⁰ W²⁸ 3663 R⁴ G¹⁰ W²⁸ 3664 R⁵ G¹⁰ W²⁸ 3665 R⁷ G¹⁰ W²⁸ 3666 R⁸ G¹⁰ W²⁸ 3667 R¹⁰ G¹⁰ W²⁸ 3668 R¹² G¹⁰ W²⁸ 3669 R¹⁴ G¹⁰ W²⁸ 3670 R¹⁵ G¹⁰ W²⁸ 3671 R¹⁹ G¹⁰ W²⁸ 3672 R²⁷ G¹⁰ W²⁸ 3673 R²⁸ G¹⁰ W²⁸ 3674 R³³ G¹⁰ W²⁸ 3675 R³⁸ G¹⁰ W²⁸ 3676 R³⁹ G¹⁰ W²⁸ 3677 R⁴¹ G¹⁰ W²⁸ 3678 R⁴⁶ G¹⁰ W²⁸ 3679 R⁴⁷ G¹⁰ W²⁸ 3680 R⁴⁹ G¹⁰ W²⁸ 3681 R¹ G²⁵ W²⁸ 3682 R² G²⁵ W²⁸ 3683 R⁴ G²⁵ W²⁸ 3684 R⁵ G²⁵ W²⁸ 3685 R⁷ G²⁵ W²⁸ 3686 R⁸ G²⁵ W²⁸ 3687 R¹⁰ G²⁵ W²⁸ 3688 R¹² G²⁵ W²⁸ 3689 R¹⁴ G²⁵ W²⁸ 3690 R¹⁵ G²⁵ W²⁸ 3691 R¹⁹ G²⁵ W²⁸ 3692 R²⁷ G²⁵ W²⁸ 3693 R²⁸ G²⁵ W²⁸ 3694 R³³ G²⁵ W²⁸ 3695 R³⁸ G²⁵ W²⁸ 3696 R³⁹ G²⁵ W²⁸ 3697 R⁴¹ G²⁵ W²⁸ 3698 R⁴⁶ G²⁵ W²⁸ 3699 R⁴⁷ G²⁵ W²⁸ 3700 R⁴⁹ G²⁵ W²⁸ 3701 R¹ G²⁶ W²⁸ 3702 R² G²⁶ W²⁸ 3703 R⁴ G²⁶ W²⁸ 3704 R⁵ G²⁶ W²⁸ 3705 R⁷ G²⁶ W²⁸ 3706 R⁸ G²⁶ W²⁸ 3707 R¹⁰ G²⁶ W²⁸ 3708 R¹² G²⁶ W²⁸ 3709 R¹⁴ G²⁶ W²⁸ 3710 R¹⁵ G²⁶ W²⁸ 3711 R¹⁹ G²⁶ W²⁸ 3712 R²⁷ G²⁶ W²⁸ 3713 R²⁸ G²⁶ W²⁸ 3714 R³³ G²⁶ W²⁸ 3715 R³⁸ G²⁶ W²⁸ 3716 R³⁹ G²⁶ W²⁸ 3717 R⁴¹ G²⁶ W²⁸ 3718 R⁴⁶ G²⁶ W²⁸ 3719 R⁴⁷ G²⁶ W²⁸ 3720 R⁴⁹ G²⁶ W²⁸ 3721 R¹ G²⁷ W²⁸ 3722 R² G²⁷ W²⁸ 3723 R⁴ G²⁷ W²⁸ 3724 R⁵ G²⁷ W²⁸ 3725 R⁷ G²⁷ W²⁸ 3726 R⁸ G²⁷ W²⁸ 3727 R¹⁰ G²⁷ W²⁸ 3728 R¹² G²⁷ W²⁸ 3729 R¹⁴ G²⁷ W²⁸ 3730 R¹⁵ G²⁷ W²⁸ 3731 R¹⁹ G²⁷ W²⁸ 3732 R²⁷ G²⁷ W²⁸ 3733 R²⁸ G²⁷ W²⁸ 3734 R³³ G²⁷ W²⁸ 3735 R³⁸ G²⁷ W²⁸ 3736 R³⁹ G²⁷ W²⁸ 3737 R⁴¹ G²⁷ W²⁸ 3738 R⁴⁶ G²⁷ W²⁸ 3739 R⁴⁷ G²⁷ W²⁸ 3740 R⁴⁹ G²⁷ W²⁸ 3741 R¹ G²⁸ W²⁸ 3742 R² G²⁸ W²⁸ 3743 R⁴ G²⁸ W²⁸ 3744 R⁵ G²⁸ W²⁸ 3745 R⁷ G²⁸ W²⁸ 3746 R⁸ G²⁸ W²⁸ 3747 R¹⁰ G²⁸ W²⁸ 3748 R¹² G²⁸ W²⁸ 3749 R¹⁴ G²⁸ W²⁸ 3750 R¹⁵ G²⁸ W²⁸ 3751 R¹⁹ G²⁸ W²⁸ 3752 R²⁷ G²⁸ W²⁸ 3753 R²⁸ G²⁸ W²⁸ 3754 R³³ G²⁸ W²⁸ 3755 R³⁸ G²⁸ W²⁸ 3756 R³⁹ G²⁸ W²⁸ 3757 R⁴¹ G²⁸ W²⁸ 3758 R⁴⁶ G²⁸ W²⁸ 3759 R⁴⁷ G²⁸ W²⁸ 3760 R⁴⁹ G²⁸ W²⁸ 3761 R¹ G¹ W³⁶ 3762 R² G¹ W³⁶ 3763 R⁴ G¹ W³⁶ 3764 R⁵ G¹ W³⁶ 3765 R⁷ G¹ W³⁶ 3766 R⁸ G¹ W³⁶ 3767 R¹⁰ G¹ W³⁶ 3768 R¹² G¹ W³⁶ 3769 R¹⁴ G¹ W³⁶ 3770 R¹⁵ G¹ W³⁶ 3771 R¹⁹ G¹ W³⁶ 3772 R²⁷ G¹ W³⁶ 3773 R²⁸ G¹ W³⁶ 3774 R³³ G¹ W³⁶ 3775 R³⁸ G¹ W³⁶ 3776 R³⁹ G¹ W³⁶ 3777 R⁴¹ G¹ W³⁶ 3778 R⁴⁶ G¹ W³⁶ 3779 R⁴⁷ G¹ W³⁶ 3780 R⁴⁹ G¹ W³⁶ 3781 R¹ G³ W³⁶ 3782 R² G³ W³⁶ 3783 R⁴ G³ W³⁶ 3784 R⁵ G³ W³⁶ 3785 R⁷ G³ W³⁶ 3786 R⁸ G³ W³⁶ 3787 R¹⁰ G³ W³⁶ 3788 R¹² G³ W³⁶ 3789 R¹⁴ G³ W³⁶ 3790 R¹⁵ G³ W³⁶ 3791 R¹⁹ G³ W³⁶ 3792 R²⁷ G³ W³⁶ 3793 R²⁸ G³ W³⁶ 3794 R³³ G³ W³⁶ 3795 R³⁸ G³ W³⁶ 3796 R³⁹ G³ W³⁶ 3797 R⁴¹ G³ W³⁶ 3798 R⁴⁶ G³ W³⁶ 3799 R⁴⁷ G³ W³⁶ 3800 R⁴⁹ G³ W³⁶ 3801 R¹ G⁵ W³⁶ 3802 R² G⁵ W³⁶ 3803 R⁴ G⁵ W³⁶ 3804 R⁵ G⁵ W³⁶ 3805 R⁷ G⁵ W³⁶ 3806 R⁸ G⁵ W³⁶ 3807 R¹⁰ G⁵ W³⁶ 3808 R¹² G⁵ W³⁶ 3809 R¹⁴ G⁵ W³⁶ 3810 R¹⁵ G⁵ W³⁶ 3811 R¹⁹ G⁵ W³⁶ 3812 R²⁷ G⁵ W³⁶ 3813 R²⁸ G⁵ W³⁶ 3814 R³³ G⁵ W³⁶ 3815 R³⁸ G⁵ W³⁶ 3816 R³⁹ G⁵ W³⁶ 3817 R⁴¹ G⁵ W³⁶ 3818 R⁴⁶ G⁵ W³⁶ 3819 R⁴⁷ G⁵ W³⁶ 3820 R⁴⁹ G⁵ W³⁶ 3821 R¹ G⁶ W³⁶ 3822 R² G⁶ W³⁶ 3823 R⁴ G⁶ W³⁶ 3824 R⁵ G⁶ W³⁶ 3825 R⁷ G⁶ W³⁶ 3826 R⁸ G⁶ W³⁶ 3827 R¹⁰ G⁶ W³⁶ 3828 R¹² G⁶ W³⁶ 3829 R¹⁴ G⁶ W³⁶ 3830 R¹⁵ G⁶ W³⁶ 3831 R¹⁹ G⁶ W³⁶ 3832 R²⁷ G⁶ W³⁶ 3833 R²⁸ G⁶ W³⁶ 3834 R³³ G⁶ W³⁶ 3835 R³⁸ G⁶ W³⁶ 3836 R³⁹ G⁶ W³⁶ 3837 R⁴¹ G⁶ W³⁶ 3838 R⁴⁶ G⁶ W³⁶ 3839 R⁴⁷ G⁶ W³⁶ 3840 R⁴⁹ G⁶ W³⁶ 3841 R¹ G⁹ W³⁶ 3842 R² G⁹ W³⁶ 3843 R⁴ G⁹ W³⁶ 3844 R⁵ G⁹ W³⁶ 3845 R⁷ G⁹ W³⁶ 3846 R⁸ G⁹ W³⁶ 3847 R¹⁰ G⁹ W³⁶ 3848 R¹² G⁹ W³⁶ 3849 R¹⁴ G⁹ W³⁶ 3850 R¹⁵ G⁹ W³⁶ 3851 R¹⁹ G⁹ W³⁶ 3852 R²⁷ G⁹ W³⁶ 3853 R²⁸ G⁹ W³⁶ 3854 R³³ G⁹ W³⁶ 3855 R³⁸ G⁹ W³⁶ 3856 R³⁹ G⁹ W³⁶ 3857 R⁴¹ G⁹ W³⁶ 3858 R⁴⁶ G⁹ W³⁶ 3859 R⁴⁷ G⁹ W³⁶ 3860 R⁴⁹ G⁹ W³⁶ 3861 R¹ G¹⁰ W³⁶ 3862 R² G¹⁰ W³⁶ 3863 R⁴ G¹⁰ W³⁶ 3864 R⁵ G¹⁰ W³⁶ 3865 R⁷ G¹⁰ W³⁶ 3866 R⁸ G¹⁰ W³⁶ 3867 R¹⁰ G¹⁰ W³⁶ 3868 R¹² G¹⁰ W³⁶ 3869 R¹⁴ G¹⁰ W³⁶ 3870 R¹⁵ G¹⁰ W³⁶ 3871 R¹⁹ G¹⁰ W³⁶ 3872 R²⁷ G¹⁰ W³⁶ 3873 R²⁸ G¹⁰ W³⁶ 3874 R³³ G¹⁰ W³⁶ 3875 R³⁸ G¹⁰ W³⁶ 3876 R³⁹ G¹⁰ W³⁶ 3877 R⁴¹ G¹⁰ W³⁶ 3878 R⁴⁶ G¹⁰ W³⁶ 3879 R⁴⁷ G¹⁰ W³⁶ 3880 R⁴⁹ G¹⁰ W³⁶ 3881 R¹ G²⁵ W³⁶ 3882 R² G²⁵ W³⁶ 3883 R⁴ G²⁵ W³⁶ 3884 R⁵ G²⁵ W³⁶ 3885 R⁷ G²⁵ W³⁶ 3886 R⁸ G²⁵ W³⁶ 3887 R¹⁰ G²⁵ W³⁶ 3888 R¹² G²⁵ W³⁶ 3889 R¹⁴ G²⁵ W³⁶ 3890 R¹⁵ G²⁵ W³⁶ 3891 R¹⁹ G²⁵ W³⁶ 3892 R²⁷ G²⁵ W³⁶ 3893 R²⁸ G²⁵ W³⁶ 3894 R³³ G²⁵ W³⁶ 3895 R³⁸ G²⁵ W³⁶ 3896 R³⁹ G²⁵ W³⁶ 3897 R⁴¹ G²⁵ W³⁶ 3898 R⁴⁶ G²⁵ W³⁶ 3899 R⁴⁷ G²⁵ W³⁶ 3900 R⁴⁹ G²⁵ W³⁶ 3901 R¹ G²⁶ W³⁶ 3902 R² G²⁶ W³⁶ 3903 R⁴ G²⁶ W³⁶ 3904 R⁵ G²⁶ W³⁶ 3905 R⁷ G²⁶ W³⁶ 3906 R⁸ G²⁶ W³⁶ 3907 R¹⁰ G²⁶ W³⁶ 3908 R¹² G²⁶ W³⁶ 3909 R¹⁴ G²⁶ W³⁶ 3910 R¹⁵ G²⁶ W³⁶ 3911 R¹⁹ G²⁶ W³⁶ 3912 R²⁷ G²⁶ W³⁶ 3913 R²⁸ G²⁶ W³⁶ 3914 R³³ G²⁶ W³⁶ 3915 R³⁸ G²⁶ W³⁶ 3916 R³⁹ G²⁶ W³⁶ 3917 R⁴¹ G²⁶ W³⁶ 3918 R⁴⁶ G²⁶ W³⁶ 3919 R⁴⁷ G²⁶ W³⁶ 3920 R⁴⁹ G²⁶ W³⁶ 3921 R¹ G²⁷ W³⁶ 3922 R² G²⁷ W³⁶ 3923 R⁴ G²⁷ W³⁶ 3924 R⁵ G²⁷ W³⁶ 3925 R⁷ G²⁷ W³⁶ 3926 R⁸ G²⁷ W³⁶ 3927 R¹⁰ G²⁷ W³⁶ 3928 R¹² G²⁷ W³⁶ 3929 R¹⁴ G²⁷ W³⁶ 3930 R¹⁵ G²⁷ W³⁶ 3931 R¹⁹ G²⁷ W³⁶ 3932 R²⁷ G²⁷ W³⁶ 3933 R²⁸ G²⁷ W³⁶ 3934 R³³ G²⁷ W³⁶ 3935 R³⁸ G²⁷ W³⁶ 3936 R³⁹ G²⁷ W³⁶ 3937 R⁴¹ G²⁷ W³⁶ 3938 R⁴⁶ G²⁷ W³⁶ 3939 R⁴⁷ G²⁷ W³⁶ 3940 R⁴⁹ G²⁷ W³⁶ 3941 R¹ G²⁸ W³⁶ 3942 R² G²⁸ W³⁶ 3943 R⁴ G²⁸ W³⁶ 3944 R⁵ G²⁸ W³⁶ 3945 R⁷ G²⁸ W³⁶ 3946 R⁸ G²⁸ W³⁶ 3947 R¹⁰ G²⁸ W³⁶ 3948 R¹² G²⁸ W³⁶ 3949 R¹⁴ G²⁸ W³⁶ 3950 R¹⁵ G²⁸ W³⁶ 3951 R¹⁹ G²⁸ W³⁶ 3952 R²⁷ G²⁸ W³⁶ 3953 R²⁸ G²⁸ W³⁶ 3954 R³³ G²⁸ W³⁶ 3955 R³⁸ G²⁸ W³⁶ 3956 R³⁹ G²⁸ W³⁶ 3957 R⁴¹ G²⁸ W³⁶ 3958 R⁴⁶ G²⁸ W³⁶ 3959 R⁴⁷ G²⁸ W³⁶ 3960 R⁴⁹ G²⁸ W³⁶ 3961 R¹ G¹ W³⁷ 3962 R² G¹ W³⁷ 3963 R⁴ G¹ W³⁷ 3964 R⁵ G¹ W³⁷ 3965 R⁷ G¹ W³⁷ 3966 R⁸ G¹ W³⁷ 3967 R¹⁰ G¹ W³⁷ 3968 R¹² G¹ W³⁷ 3969 R¹⁴ G¹ W³⁷ 3970 R¹⁵ G¹ W³⁷ 3971 R¹⁹ G¹ W³⁷ 3972 R²⁷ G¹ W³⁷ 3973 R²⁸ G¹ W³⁷ 3974 R³³ G¹ W³⁷ 3975 R³⁸ G¹ W³⁷ 3976 R³⁹ G¹ W³⁷ 3977 R⁴¹ G¹ W³⁷ 3978 R⁴⁶ G¹ W³⁷ 3979 R⁴⁷ G¹ W³⁷ 3980 R⁴⁹ G¹ W³⁷ 3981 R¹ G³ W³⁷ 3982 R² G³ W³⁷ 3983 R⁴ G³ W³⁷ 3984 R⁵ G³ W³⁷ 3985 R⁷ G³ W³⁷ 3986 R⁸ G³ W³⁷ 3987 R¹⁰ G³ W³⁷ 3988 R¹² G³ W³⁷ 3989 R¹⁴ G³ W³⁷ 3990 R¹⁵ G³ W³⁷ 3991 R¹⁹ G³ W³⁷ 3992 R²⁷ G³ W³⁷ 3993 R²⁸ G³ W³⁷ 3994 R³³ G³ W³⁷ 3995 R³⁸ G³ W³⁷ 3996 R³⁹ G³ W³⁷ 3997 R⁴¹ G³ W³⁷ 3998 R⁴⁶ G³ W³⁷ 3999 R⁴⁷ G³ W³⁷ 4000 R⁴⁹ G³ W³⁷ 4001 R¹ G⁵ W³⁷ 4002 R² G⁵ W³⁷ 4003 R⁴ G⁵ W³⁷ 4004 R⁵ G⁵ W³⁷ 4005 R⁷ G⁵ W³⁷ 4006 R⁸ G⁵ W³⁷ 4007 R¹⁰ G⁵ W³⁷ 4008 R¹² G⁵ W³⁷ 4009 R¹⁴ G⁵ W³⁷ 4010 R¹⁵ G⁵ W³⁷ 4011 R¹⁹ G⁵ W³⁷ 4012 R²⁷ G⁵ W³⁷ 4013 R²⁸ G⁵ W³⁷ 4014 R³³ G⁵ W³⁷ 4015 R³⁸ G⁵ W³⁷ 4016 R³⁹ G⁵ W³⁷ 4017 R⁴¹ G⁵ W³⁷ 4018 R⁴⁶ G⁵ W³⁷ 4019 R⁴⁷ G⁵ W³⁷ 4020 R⁴⁹ G⁵ W³⁷ 4021 R¹ G⁶ W³⁷ 4022 R² G⁶ W³⁷ 4023 R⁴ G⁶ W³⁷ 4024 R⁵ G⁶ W³⁷ 4025 R⁷ G⁶ W³⁷ 4026 R⁸ G⁶ W³⁷ 4027 R¹⁰ G⁶ W³⁷ 4028 R¹² G⁶ W³⁷ 4029 R¹⁴ G⁶ W³⁷ 4030 R¹⁵ G⁶ W³⁷ 4031 R¹⁹ G⁶ W³⁷ 4032 R²⁷ G⁶ W³⁷ 4033 R²⁸ G⁶ W³⁷ 4034 R³³ G⁶ W³⁷ 4035 R³⁸ G⁶ W³⁷ 4036 R³⁹ G⁶ W³⁷ 4037 R⁴¹ G⁶ W³⁷ 4038 R⁴⁶ G⁶ W³⁷ 4039 R⁴⁷ G⁶ W³⁷ 4040 R⁴⁹ G⁶ W³⁷ 4041 R¹ G⁹ W³⁷ 4042 R² G⁹ W³⁷ 4043 R⁴ G⁹ W³⁷ 4044 R⁵ G⁹ W³⁷ 4045 R⁷ G⁹ W³⁷ 4046 R⁸ G⁹ W³⁷ 4047 R¹⁰ G⁹ W³⁷ 4048 R¹² G⁹ W³⁷ 4049 R¹⁴ G⁹ W³⁷ 4050 R¹⁵ G⁹ W³⁷ 4051 R¹⁹ G⁹ W³⁷ 4052 R²⁷ G⁹ W³⁷ 4053 R²⁸ G⁹ W³⁷ 4054 R³³ G⁹ W³⁷ 4055 R³⁸ G⁹ W³⁷ 4056 R³⁹ G⁹ W³⁷ 4057 R⁴¹ G⁹ W³⁷ 4058 R⁴⁶ G⁹ W³⁷ 4059 R⁴⁷ G⁹ W³⁷ 4060 R⁴⁹ G⁹ W³⁷ 4061 R¹ G¹⁰ W³⁷ 4062 R² G¹⁰ W³⁷ 4063 R⁴ G¹⁰ W³⁷ 4064 R⁵ G¹⁰ W³⁷ 4065 R⁷ G¹⁰ W³⁷ 4066 R⁸ G¹⁰ W³⁷ 4067 R¹⁰ G¹⁰ W³⁷ 4068 R¹² G¹⁰ W³⁷ 4069 R¹⁴ G¹⁰ W³⁷ 4070 R¹⁵ G¹⁰ W³⁷ 4071 R¹⁹ G¹⁰ W³⁷ 4072 R²⁷ G¹⁰ W³⁷ 4073 R²⁸ G¹⁰ W³⁷ 4074 R³³ G¹⁰ W³⁷ 4075 R³⁸ G¹⁰ W³⁷ 4076 R³⁹ G¹⁰ W³⁷ 4077 R⁴¹ G¹⁰ W³⁷ 4078 R⁴⁶ G¹⁰ W³⁷ 4079 R⁴⁷ G¹⁰ W³⁷ 4080 R⁴⁹ G¹⁰ W³⁷ 4081 R¹ G²⁵ W³⁷ 4082 R² G²⁵ W³⁷ 4083 R⁴ G²⁵ W³⁷ 4084 R⁵ G²⁵ W³⁷ 4085 R⁷ G²⁵ W³⁷ 4086 R⁸ G²⁵ W³⁷ 4087 R¹⁰ G²⁵ W³⁷ 4088 R¹² G²⁵ W³⁷ 4089 R¹⁴ G²⁵ W³⁷ 4090 R¹⁵ G²⁵ W³⁷ 4091 R¹⁹ G²⁵ W³⁷ 4092 R²⁷ G²⁵ W³⁷ 4093 R²⁸ G²⁵ W³⁷ 4094 R³³ G²⁵ W³⁷ 4095 R³⁸ G²⁵ W³⁷ 4096 R³⁹ G²⁵ W³⁷ 4097 R⁴¹ G²⁵ W³⁷ 4098 R⁴⁶ G²⁵ W³⁷ 4099 R⁴⁷ G²⁵ W³⁷ 4100 R⁴⁹ G²⁵ W³⁷ 4101 R¹ G²⁶ W³⁷ 4102 R² G²⁶ W³⁷ 4103 R⁴ G²⁶ W³⁷ 4104 R⁵ G²⁶ W³⁷ 4105 R⁷ G²⁶ W³⁷ 4106 R⁸ G²⁶ W³⁷ 4107 R¹⁰ G²⁶ W³⁷ 4108 R¹² G²⁶ W³⁷ 4109 R¹⁴ G²⁶ W³⁷ 4110 R¹⁵ G²⁶ W³⁷ 4111 R¹⁹ G²⁶ W³⁷ 4112 R²⁷ G²⁶ W³⁷ 4113 R²⁸ G²⁶ W³⁷ 4114 R³³ G²⁶ W³⁷ 4115 R³⁸ G²⁶ W³⁷ 4116 R³⁹ G²⁶ W³⁷ 4117 R⁴¹ G²⁶ W³⁷ 4118 R⁴⁶ G²⁶ W³⁷ 4119 R⁴⁷ G²⁶ W³⁷ 4120 R⁴⁹ G²⁶ W³⁷ 4121 R¹ G²⁷ W³⁷ 4122 R² G²⁷ W³⁷ 4123 R⁴ G²⁷ W³⁷ 4124 R⁵ G²⁷ W³⁷ 4125 R⁷ G²⁷ W³⁷ 4126 R⁸ G²⁷ W³⁷ 4127 R¹⁰ G²⁷ W³⁷ 4128 R¹² G²⁷ W³⁷ 4129 R¹⁴ G²⁷ W³⁷ 4130 R¹⁵ G²⁷ W³⁷ 4131 R¹⁹ G²⁷ W³⁷ 4132 R²⁷ G²⁷ W³⁷ 4133 R²⁸ G²⁷ W³⁷ 4134 R³³ G²⁷ W³⁷ 4135 R³⁸ G²⁷ W³⁷ 4136 R³⁹ G²⁷ W³⁷ 4137 R⁴¹ G²⁷ W³⁷ 4138 R⁴⁶ G²⁷ W³⁷ 4139 R⁴⁷ G²⁷ W³⁷ 4140 R⁴⁹ G²⁷ W³⁷ 4141 R¹ G²⁸ W³⁷ 4142 R² G²⁸ W³⁷ 4143 R⁴ G²⁸ W³⁷ 4144 R⁵ G²⁸ W³⁷ 4145 R⁷ G²⁸ W³⁷ 4146 R⁸ G²⁸ W³⁷ 4147 R¹⁰ G²⁸ W³⁷ 4148 R¹² G²⁸ W³⁷ 4149 R¹⁴ G²⁸ W³⁷ 4150 R¹⁵ G²⁸ W³⁷ 4151 R¹⁹ G²⁸ W³⁷ 4152 R²⁷ G²⁸ W³⁷ 4153 R²⁸ G²⁸ W³⁷ 4154 R³³ G²⁸ W³⁷ 4155 R³⁸ G²⁸ W³⁷ 4156 R³⁹ G²⁸ W³⁷ 4157 R⁴¹ G²⁸ W³⁷ 4158 R⁴⁶ G²⁸ W³⁷ 4159 R⁴⁷ G²⁸ W³⁷ 4160 R⁴⁹ G²⁸ W³⁷ 4161 R¹ G⁷ W¹ 4162 R² G⁷ W¹ 4163 R⁴ G⁷ W¹ 4164 R⁵ G⁷ W¹ 4165 R⁷ G⁷ W¹ 4166 R⁸ G⁷ W¹ 4167 R¹⁰ G⁷ W¹ 4168 R¹² G⁷ W¹ 4169 R¹⁴ G⁷ W¹ 4170 R¹⁵ G⁷ W¹ 4171 R¹⁹ G⁷ W¹ 4172 R²⁷ G⁷ W¹ 4173 R²⁸ G⁷ W¹ 4174 R³³ G⁷ W¹ 4175 R³⁸ G⁷ W¹ 4176 R³⁹ G⁷ W¹ 4177 R⁴¹ G⁷ W¹ 4178 R⁴⁶ G⁷ W¹ 4179 R⁴⁷ G⁷ W¹ 4180 R⁴⁹ G⁷ W¹ 4181 R¹ G⁸ W¹ 4182 R² G⁸ W¹ 4183 R⁴ G⁸ W¹ 4184 R⁵ G⁸ W¹ 4185 R⁷ G⁸ W¹ 4186 R⁸ G⁸ W¹ 4187 R¹⁰ G⁸ W¹ 4188 R¹² G⁸ W¹ 4189 R¹⁴ G⁸ W¹ 4190 R¹⁵ G⁸ W¹ 4191 R¹⁹ G⁸ W¹ 4192 R²⁷ G⁸ W¹ 4193 R²⁸ G⁸ W¹ 4194 R³³ G⁸ W¹ 4195 R³⁸ G⁸ W¹ 4196 R³⁹ G⁸ W¹ 4197 R⁴¹ G⁸ W¹ 4198 R⁴⁶ G⁸ W¹ 4199 R⁴⁷ G⁸ W¹ 4200 R⁴⁹ G⁸ W¹ 4201 R¹ G⁷ W¹¹ 4202 R² G⁷ W¹¹ 4203 R⁴ G⁷ W¹¹ 4204 R⁵ G⁷ W¹¹ 4205 R⁷ G⁷ W¹¹ 4206 R⁸ G⁷ W¹¹ 4207 R¹⁰ G⁷ W¹¹ 4208 R¹² G⁷ W¹¹ 4209 R¹⁴ G⁷ W¹¹ 4210 R¹⁵ G⁷ W¹¹ 4211 R¹⁹ G⁷ W¹¹ 4212 R²⁷ G⁷ W¹¹ 4213 R²⁸ G⁷ W¹¹ 4214 R³³ G⁷ W¹¹ 4215 R³⁸ G⁷ W¹¹ 4216 R³⁹ G⁷ W¹¹ 4217 R⁴¹ G⁷ W¹¹ 4218 R⁴⁶ G⁷ W¹¹ 4219 R⁴⁷ G⁷ W¹¹ 4220 R⁴⁹ G⁷ W¹¹ 4221 R¹ G⁸ W¹¹ 4222 R² G⁸ W¹¹ 4223 R⁴ G⁸ W¹¹ 4224 R⁵ G⁸ W¹¹ 4225 R⁷ G⁸ W¹¹ 4226 R⁸ G⁸ W¹¹ 4227 R¹⁰ G⁸ W¹¹ 4228 R¹² G⁸ W¹¹ 4229 R¹⁴ G⁸ W¹¹ 4230 R¹⁵ G⁸ W¹¹ 4231 R¹⁹ G⁸ W¹¹ 4232 R²⁷ G⁸ W¹¹ 4233 R²⁸ G⁸ W¹¹ 4234 R³³ G⁸ W¹¹ 4235 R³⁸ G⁸ W¹¹ 4236 R³⁹ G⁸ W¹¹ 4237 R⁴¹ G⁸ W¹¹ 4238 R⁴⁶ G⁸ W¹¹ 4239 R⁴⁷ G⁸ W¹¹ 4240 R⁴⁹ G⁸ W¹¹ 4241 R⁴ G² W³ 4242 R⁴ G² W⁴ 4243 R⁴ G² W⁷ 4244 R⁴ G² W⁸ 4245 R⁴ G² W⁹ 4246 R⁴ G² W¹⁰ 4247 R⁴ G² W¹² 4248 R⁴ G² W¹³ 4249 R⁴ G² W¹⁴ 4250 R⁴ G² W¹⁵ 4251 R⁴ G² W¹⁶ 4252 R⁴ G² W¹⁸ 4253 R⁴ G² W¹⁹ 4254 R⁴ G² W²⁰ 4255 R⁴ G² W²² 4256 R⁴ G² W²³ 4257 R⁴ G² W²⁴ 4258 R⁴ G² W²⁵ 4259 R⁴ G² W²⁶ 4260 R⁴ G² W²⁷ 4261 R⁴ G² W²⁹ 4262 R⁴ G² W³⁰ 4263 R⁴ G² W³¹ 4264 R⁴ G² W³² 4265 R⁴ G² W³³ 4266 R⁴ G² W³⁴ 4267 R⁴ G² W³⁵ 4268 R⁴ G² W³⁸ 4269 R⁴ G² W³⁹ 4270 R⁴ G² W⁴⁰ 4271 R⁸ G² W³ 4272 R⁸ G² W⁴ 4273 R⁸ G² W⁷ 4274 R⁸ G² W⁸ 4275 R⁸ G² W⁹ 4276 R⁸ G² W¹⁰ 4277 R⁸ G² W¹² 4278 R⁸ G² W¹³ 4279 R⁸ G² W¹⁴ 4280 R⁸ G² W¹⁵ 4281 R⁸ G² W¹⁶ 4282 R⁸ G² W¹⁸ 4283 R⁸ G² W¹⁹ 4284 R⁸ G² W²⁰ 4285 R⁸ G² W²² 4286 R⁸ G² W²³ 4287 R⁸ G² W²⁴ 4288 R⁸ G² W²⁵ 4289 R⁸ G² W²⁶ 4290 R⁸ G² W²⁷ 4291 R⁸ G² W²⁹ 4292 R⁸ G² W³⁰ 4293 R⁸ G² W³¹ 4294 R⁸ G² W³² 4295 R⁸ G² W³³ 4296 R⁸ G² W³⁴ 4297 R⁸ G² W³⁵ 4298 R⁸ G² W³⁸ 4299 R⁸ G² W³⁹ 4300 R⁸ G² W⁴⁰ 4301 R¹⁹ G² W³ 4302 R¹⁹ G² W⁴ 4303 R¹⁹ G² W⁷ 4304 R¹⁹ G² W⁸ 4305 R¹⁹ G² W⁹ 4306 R¹⁹ G² W¹⁰ 4307 R¹⁹ G² W¹² 4308 R¹⁹ G² W¹³ 4309 R¹⁹ G² W¹⁴ 4310 R¹⁹ G² W¹⁵ 4311 R¹⁹ G² W¹⁶ 4312 R¹⁹ G² W¹⁸ 4313 R¹⁹ G² W¹⁹ 4314 R¹⁹ G² W²⁰ 4315 R¹⁹ G² W²² 4316 R¹⁹ G² W²³ 4317 R¹⁹ G² W²⁴ 4318 R¹⁹ G² W²⁵ 4319 R¹⁹ G² W²⁶ 4320 R¹⁹ G² W²⁷ 4321 R¹⁹ G² W²⁹ 4322 R¹⁹ G² W³⁰ 4323 R¹⁹ G² W³¹ 4324 R¹⁹ G² W³² 4325 R¹⁹ G² W³³ 4326 R¹⁹ G² W³⁴ 4327 R¹⁹ G² W³⁵ 4328 R¹⁹ G² W³⁸ 4329 R¹⁹ G² W³⁹ 4330 R¹⁹ G² W⁴⁰ 4331 R⁴ G⁴ W³ 4332 R⁴ G⁴ W⁴ 4333 R⁴ G⁴ W⁷ 4334 R⁴ G⁴ W⁸ 4335 R⁴ G⁴ W⁹ 4336 R⁴ G⁴ W¹⁰ 4337 R⁴ G⁴ W¹² 4338 R⁴ G⁴ W¹³ 4339 R⁴ G⁴ W¹⁴ 4340 R⁴ G⁴ W¹⁵ 4341 R⁴ G⁴ W¹⁶ 4342 R⁴ G⁴ W¹⁸ 4343 R⁴ G⁴ W¹⁹ 4344 R⁴ G⁴ W²⁰ 4345 R⁴ G⁴ W²² 4346 R⁴ G⁴ W²³ 4347 R⁴ G⁴ W²⁴ 4348 R⁴ G⁴ W²⁵ 4349 R⁴ G⁴ W²⁶ 4350 R⁴ G⁴ W²⁷ 4351 R⁴ G⁴ W²⁹ 4352 R⁴ G⁴ W³⁰ 4353 R⁴ G⁴ W³¹ 4354 R⁴ G⁴ W³² 4355 R⁴ G⁴ W³³ 4356 R⁴ G⁴ W³⁴ 4357 R⁴ G⁴ W³⁵ 4358 R⁴ G⁴ W³⁸ 4359 R⁴ G⁴ W³⁹ 4360 R⁴ G⁴ W⁴⁰ 4361 R⁸ G⁴ W³ 4362 R⁸ G⁴ W⁴ 4363 R⁸ G⁴ W⁷ 4364 R⁸ G⁴ W⁸ 4365 R⁸ G⁴ W⁹ 4366 R⁸ G⁴ W¹⁰ 4367 R⁸ G⁴ W¹² 4368 R⁸ G⁴ W¹³ 4369 R⁸ G⁴ W¹⁴ 4370 R⁸ G⁴ W¹⁵ 4371 R⁸ G⁴ W¹⁶ 4372 R⁸ G⁴ W¹⁸ 4373 R⁸ G⁴ W¹⁹ 4374 R⁸ G⁴ W²⁰ 4375 R⁸ G⁴ W²² 4376 R⁸ G⁴ W²³ 4377 R⁸ G⁴ W²⁴ 4378 R⁸ G⁴ W²⁵ 4379 R⁸ G⁴ W²⁶ 4380 R⁸ G⁴ W²⁷ 4381 R⁸ G⁴ W²⁹ 4382 R⁸ G⁴ W³⁰ 4383 R⁸ G⁴ W³¹ 4384 R⁸ G⁴ W³² 4385 R⁸ G⁴ W³³ 4386 R⁸ G⁴ W³⁴ 4387 R⁸ G⁴ W³⁵ 4388 R⁸ G⁴ W³⁸ 4389 R⁸ G⁴ W³⁹ 4390 R⁸ G⁴ W⁴⁰ 4391 R¹⁹ G⁴ W³ 4392 R¹⁹ G⁴ W⁴ 4393 R¹⁹ G⁴ W⁷ 4394 R¹⁹ G⁴ W⁸ 4395 R¹⁹ G⁴ W⁹ 4396 R¹⁹ G⁴ W¹⁰ 4397 R¹⁹ G⁴ W¹² 4398 R¹⁹ G⁴ W¹³ 4399 R¹⁹ G⁴ W¹⁴ 4400 R¹⁹ G⁴ W¹⁵ 4401 R¹⁹ G⁴ W¹⁶ 4402 R¹⁹ G⁴ W¹⁸ 4403 R¹⁹ G⁴ W¹⁹ 4404 R¹⁹ G⁴ W²⁰ 4405 R¹⁹ G⁴ W²² 4406 R¹⁹ G⁴ W²³ 4407 R¹⁹ G⁴ W²⁴ 4408 R¹⁹ G⁴ W²⁵ 4409 R¹⁹ G⁴ W²⁶ 4410 R¹⁹ G⁴ W²⁷ 4411 R¹⁹ G⁴ W²⁹ 4412 R¹⁹ G⁴ W³⁰ 4413 R¹⁹ G⁴ W³¹ 4414 R¹⁹ G⁴ W³² 4415 R¹⁹ G⁴ W³³ 4416 R¹⁹ G⁴ W³⁴ 4417 R¹⁹ G⁴ W³⁵ 4418 R¹⁹ G⁴ W³⁸ 4419 R¹⁹ G⁴ W³⁹ 4420 R¹⁹ G⁴ W⁴⁰ 4421 R¹ G² W⁴² 4422 R² G² W⁴² 4423 R³ G² W⁴² 4424 R⁴ G² W⁴² 4425 R⁵ G² W⁴² 4426 R⁶ G² W⁴² 4427 R⁷ G² W⁴² 4428 R⁸ G² W⁴² 4429 R⁹ G² W⁴² 4430 R¹⁰ G² W⁴² 4431 R¹¹ G² W⁴² 4432 R¹² G² W⁴² 4433 R¹³ G² W⁴² 4434 R¹⁴ G² W⁴² 4435 R¹⁵ G² W⁴² 4436 R¹⁶ G² W⁴² 4437 R¹⁷ G² W⁴² 4438 R¹⁸ G² W⁴² 4439 R¹⁹ G² W⁴² 4440 R²⁰ G² W⁴² 4441 R²¹ G² W⁴² 4442 R²² G² W⁴² 4443 R²³ G² W⁴² 4444 R²⁴ G² W⁴² 4445 R²⁵ G² W⁴² 4446 R²⁶ G² W⁴² 4447 R²⁷ G² W⁴² 4448 R²⁸ G² W⁴² 4449 R²⁹ G² W⁴² 4450 R³⁰ G² W⁴² 4451 R³¹ G² W⁴² 4452 R³² G² W⁴² 4453 R³³ G² W⁴² 4454 R³⁴ G² W⁴² 4455 R³⁵ G² W⁴² 4456 R³⁶ G² W⁴² 4457 R³⁷ G² W⁴² 4458 R³⁸ G² W⁴² 4459 R³⁹ G² W⁴² 4460 R⁴⁰ G² W⁴² 4461 R⁴¹ G² W⁴² 4462 R⁴² G² W⁴² 4463 R⁴³ G² W⁴² 4464 R⁴⁴ G² W⁴² 4465 R⁴⁵ G² W⁴² 4466 R⁴⁶ G² W⁴² 4467 R⁴⁷ G² W⁴² 4468 R⁴⁸ G² W⁴² 4469 R⁴⁹ G² W⁴² 4470 R⁵⁰ G² W⁴² 4471 R¹ G⁴ W⁴² 4472 R² G⁴ W⁴² 4473 R³ G⁴ W⁴² 4474 R⁴ G⁴ W⁴² 4475 R⁵ G⁴ W⁴² 4476 R⁶ G⁴ W⁴² 4477 R⁷ G⁴ W⁴² 4478 R⁸ G⁴ W⁴² 4479 R⁹ G⁴ W⁴² 4480 R¹⁰ G⁴ W⁴² 4481 R¹¹ G⁴ W⁴² 4482 R¹² G⁴ W⁴² 4483 R¹³ G⁴ W⁴² 4484 R¹⁴ G⁴ W⁴² 4485 R¹⁵ G⁴ W⁴² 4486 R¹⁶ G⁴ W⁴² 4487 R¹⁷ G⁴ W⁴² 4488 R¹⁸ G⁴ W⁴² 4489 R¹⁹ G⁴ W⁴² 4490 R²⁰ G⁴ W⁴² 4491 R²¹ G⁴ W⁴² 4492 R²² G⁴ W⁴² 4493 R²³ G⁴ W⁴² 4494 R²⁴ G⁴ W⁴² 4495 R²⁵ G⁴ W⁴² 4496 R²⁶ G⁴ W⁴² 4497 R²⁷ G⁴ W⁴² 4498 R²⁸ G⁴ W⁴² 4499 R²⁹ G⁴ W⁴² 4500 R³⁰ G⁴ W⁴² 4501 R³¹ G⁴ W⁴² 4502 R³² G⁴ W⁴² 4503 R³³ G⁴ W⁴² 4504 R³⁴ G⁴ W⁴² 4505 R³⁵ G⁴ W⁴² 4506 R³⁶ G⁴ W⁴² 4507 R³⁷ G⁴ W⁴² 4508 R³⁸ G⁴ W⁴² 4509 R³⁹ G⁴ W⁴² 4510 R⁴⁰ G⁴ W⁴² 4511 R⁴¹ G⁴ W⁴² 4512 R⁴² G⁴ W⁴² 4513 R⁴³ G⁴ W⁴² 4514 R⁴⁴ G⁴ W⁴² 4515 R⁴⁵ G⁴ W⁴² 4516 R⁴⁶ G⁴ W⁴² 4517 R⁴⁷ G⁴ W⁴² 4518 R⁴⁸ G⁴ W⁴² 4519 R⁴⁹ G⁴ W⁴² 4520 R⁵⁰ G⁴ W⁴² 4521 R¹ G¹ W⁴² 4522 R² G¹ W⁴² 4523 R⁴ G¹ W⁴² 4524 R⁵ G¹ W⁴² 4525 R⁷ G¹ W⁴² 4526 R⁸ G¹ W⁴² 4527 R¹⁰ G¹ W⁴² 4528 R¹² G¹ W⁴² 4529 R¹⁴ G¹ W⁴² 4530 R¹⁵ G¹ W⁴² 4531 R¹⁹ G¹ W⁴² 4532 R²⁷ G¹ W⁴² 4533 R²⁸ G¹ W⁴² 4534 R³³ G¹ W⁴² 4535 R³⁸ G¹ W⁴² 4536 R³⁹ G¹ W⁴² 4537 R⁴¹ G¹ W⁴² 4538 R⁴⁶ G¹ W⁴² 4539 R⁴⁷ G¹ W⁴² 4540 R⁴⁹ G¹ W⁴² 4541 R¹ G³ W⁴² 4542 R² G³ W⁴² 4543 R⁴ G³ W⁴² 4544 R⁵ G³ W⁴² 4545 R⁷ G³ W⁴² 4546 R⁸ G³ W⁴² 4547 R¹⁰ G³ W⁴² 4548 R¹² G³ W⁴² 4549 R¹⁴ G³ W⁴² 4550 R¹⁵ G³ W⁴² 4551 R¹⁹ G³ W⁴² 4552 R²⁷ G³ W⁴² 4553 R²⁸ G³ W⁴² 4554 R³³ G³ W⁴² 4555 R³⁸ G³ W⁴² 4556 R³⁹ G³ W⁴² 4557 R⁴¹ G³ W⁴² 4558 R⁴⁶ G³ W⁴² 4559 R⁴⁷ G³ W⁴² 4560 R⁴⁹ G³ W⁴² 4561 R¹ G⁹ W⁴² 4562 R² G⁹ W⁴² 4563 R⁴ G⁹ W⁴² 4564 R⁵ G⁹ W⁴² 4565 R⁷ G⁹ W⁴² 4566 R⁸ G⁹ W⁴² 4567 R¹⁰ G⁹ W⁴² 4568 R¹² G⁹ W⁴² 4569 R¹⁴ G⁹ W⁴² 4570 R¹⁵ G⁹ W⁴² 4571 R¹⁹ G⁹ W⁴² 4572 R²⁷ G⁹ W⁴² 4573 R²⁸ G⁹ W⁴² 4574 R³³ G⁹ W⁴² 4575 R³⁸ G⁹ W⁴² 4576 R³⁹ G⁹ W⁴² 4577 R⁴¹ G⁹ W⁴² 4578 R⁴⁶ G⁹ W⁴² 4579 R⁴⁷ G⁹ W⁴² 4580 R⁴⁹ G⁹ W⁴² 4581 R¹ G¹⁰ W⁴² 4582 R² G¹⁰ W⁴² 4583 R⁴ G¹⁰ W⁴² 4584 R⁵ G¹⁰ W⁴² 4585 R⁷ G¹⁰ W⁴² 4586 R⁸ G¹⁰ W⁴² 4587 R¹⁰ G¹⁰ W⁴² 4588 R¹² G¹⁰ W⁴² 4589 R¹⁴ G¹⁰ W⁴² 4590 R¹⁵ G¹⁰ W⁴² 4591 R¹⁹ G¹⁰ W⁴² 4592 R²⁷ G¹⁰ W⁴² 4593 R²⁸ G¹⁰ W⁴² 4594 R³³ G¹⁰ W⁴² 4595 R³⁸ G¹⁰ W⁴² 4596 R³⁹ G¹⁰ W⁴² 4597 R⁴¹ G¹⁰ W⁴² 4598 R⁴⁶ G¹⁰ W⁴² 4599 R⁴⁷ G¹⁰ W⁴² 4600 R⁴⁹ G¹⁰ W⁴² 4601 R¹ G¹² W⁴² 4602 R² G¹² W⁴² 4603 R⁴ G¹² W⁴² 4604 R⁵ G¹² W⁴² 4605 R⁷ G¹² W⁴² 4606 R⁸ G¹² W⁴² 4607 R¹⁰ G¹² W⁴² 4608 R¹² G¹² W⁴² 4609 R¹⁴ G¹² W⁴² 4610 R¹⁵ G¹² W⁴² 4611 R¹⁹ G¹² W⁴² 4612 R²⁷ G¹² W⁴² 4613 R²⁸ G¹² W⁴² 4614 R³³ G¹² W⁴² 4615 R³⁸ G¹² W⁴² 4616 R³⁹ G¹² W⁴² 4617 R⁴¹ G¹² W⁴² 4618 R⁴⁶ G¹² W⁴² 4619 R⁴⁷ G¹² W⁴² 4620 R⁴⁹ G¹² W⁴² 4621 R¹ G¹³ W⁴² 4622 R² G¹³ W⁴² 4623 R⁴ G¹³ W⁴² 4624 R⁵ G¹³ W⁴² 4625 R⁷ G¹³ W⁴² 4626 R⁸ G¹³ W⁴² 4627 R¹⁰ G¹³ W⁴² 4628 R¹² G¹³ W⁴² 4629 R¹⁴ G¹³ W⁴² 4630 R¹⁵ G¹³ W⁴² 4631 R¹⁹ G¹³ W⁴² 4632 R²⁷ G¹³ W⁴² 4633 R²⁸ G¹³ W⁴² 4634 R³³ G¹³ W⁴² 4635 R³⁸ G¹³ W⁴² 4636 R³⁹ G¹³ W⁴² 4637 R⁴¹ G¹³ W⁴² 4638 R⁴⁶ G¹³ W⁴² 4639 R⁴⁷ G¹³ W⁴² 4640 R⁴⁹ G¹³ W⁴² 4641 R¹ G¹⁶ W⁴² 4642 R² G¹⁶ W⁴² 4643 R⁴ G¹⁶ W⁴² 4644 R⁵ G¹⁶ W⁴² 4645 R⁷ G¹⁶ W⁴² 4646 R⁸ G¹⁶ W⁴² 4647 R¹⁰ G¹⁶ W⁴² 4648 R¹² G¹⁶ W⁴² 4649 R¹⁴ G¹⁶ W⁴² 4650 R¹⁵ G¹⁶ W⁴² 4651 R¹⁹ G¹⁶ W⁴² 4652 R²⁷ G¹⁶ W⁴² 4653 R²⁸ G¹⁶ W⁴² 4654 R³³ G¹⁶ W⁴² 4655 R³⁸ G¹⁶ W⁴² 4656 R³⁹ G¹⁶ W⁴² 4657 R⁴¹ G¹⁶ W⁴² 4658 R⁴⁶ G¹⁶ W⁴² 4659 R⁴⁷ G¹⁶ W⁴² 4660 R⁴⁹ G¹⁶ W⁴² 4661 R¹ G¹⁷ W⁴² 4662 R² G¹⁷ W⁴² 4663 R⁴ G¹⁷ W⁴² 4664 R⁵ G¹⁷ W⁴² 4665 R⁷ G¹⁷ W⁴² 4666 R⁸ G¹⁷ W⁴² 4667 R¹⁰ G¹⁷ W⁴² 4668 R¹² G¹⁷ W⁴² 4669 R¹⁴ G¹⁷ W⁴² 4670 R¹⁵ G¹⁷ W⁴² 4671 R¹⁹ G¹⁷ W⁴² 4672 R²⁷ G¹⁷ W⁴² 4673 R²⁸ G¹⁷ W⁴² 4674 R³³ G¹⁷ W⁴² 4675 R³⁸ G¹⁷ W⁴² 4676 R³⁹ G¹⁷ W⁴² 4677 R⁴¹ G¹⁷ W⁴² 4678 R⁴⁶ G¹⁷ W⁴² 4679 R⁴⁷ G¹⁷ W⁴² 4680 R⁴⁹ G¹⁷ W⁴² 4681 R¹ G²² W⁴² 4682 R² G²² W⁴² 4683 R⁴ G²² W⁴² 4684 R⁵ G²² W⁴² 4685 R⁷ G²² W⁴² 4686 R⁸ G²² W⁴² 4687 R¹⁰ G²² W⁴² 4688 R¹² G²² W⁴² 4689 R¹⁴ G²² W⁴² 4690 R¹⁵ G²² W⁴² 4691 R¹⁹ G²² W⁴² 4692 R²⁷ G²² W⁴² 4693 R²⁸ G²² W⁴² 4694 R³³ G²² W⁴² 4695 R³⁸ G²² W⁴² 4696 R³⁹ G²² W⁴² 4697 R⁴¹ G²² W⁴² 4698 R⁴⁶ G²² W⁴² 4699 R⁴⁷ G²² W⁴² 4700 R⁴⁹ G²² W⁴² 4701 R¹ G²³ W⁴² 4702 R² G²³ W⁴² 4703 R⁴ G²³ W⁴² 4704 R⁵ G²³ W⁴² 4705 R⁷ G²³ W⁴² 4706 R⁸ G²³ W⁴² 4707 R¹⁰ G²³ W⁴² 4708 R¹² G²³ W⁴² 4709 R¹⁴ G²³ W⁴² 4710 R¹⁵ G²³ W⁴² 4711 R¹⁹ G²³ W⁴² 4712 R²⁷ G²³ W⁴² 4713 R²⁸ G²³ W⁴² 4714 R³³ G²³ W⁴² 4715 R³⁸ G²³ W⁴² 4716 R³⁹ G²³ W⁴² 4717 R⁴¹ G²³ W⁴² 4718 R⁴⁶ G²³ W⁴² 4719 R⁴⁷ G²³ W⁴² 4720 R⁴⁹ G²³ W⁴² 4721 R¹ G²⁴ W⁴² 4722 R² G²⁴ W⁴² 4723 R⁴ G²⁴ W⁴² 4724 R⁵ G²⁴ W⁴² 4725 R⁷ G²⁴ W⁴² 4726 R⁸ G²⁴ W⁴² 4727 R¹⁰ G²⁴ W⁴² 4728 R¹² G²⁴ W⁴² 4729 R¹⁴ G²⁴ W⁴² 4730 R¹⁵ G²⁴ W⁴² 4731 R¹⁹ G²⁴ W⁴² 4732 R²⁷ G²⁴ W⁴² 4733 R²⁸ G²⁴ W⁴² 4734 R³³ G²⁴ W⁴² 4735 R³⁸ G²⁴ W⁴² 4736 R³⁹ G²⁴ W⁴² 4737 R⁴¹ G²⁴ W⁴² 4738 R⁴⁶ G²⁴ W⁴² 4739 R⁴⁷ G²⁴ W⁴² 4740 R⁴⁹ G²⁴ W⁴² wherein R¹ to R⁵⁰ have the following structures:

wherein G¹ to G⁴⁰ have the following structures:

wherein W¹ to W⁴² have the following structures:

In some embodiments, the compound can have a formula of M(L_(A))_(p)(L_(B))_(q)(L_(C))_(r) wherein L_(B) and L_(C) are each a bidentate ligand; and wherein p is 1, 2, or 3; q is 0, 1, or 2; r is 0, 1, or 2; and p+q+r is the oxidation state of the metal M.

In some embodiments, the compound can have a formula selected from the group consisting of Ir(L_(A))₃, Ir(L_(A))(L_(B))₂, Ir(L_(A))₂(L_(B)), Ir(L_(A))₂(L_(C)), and Ir(L_(A))(L_(B))(L_(C)); and wherein L_(A), L_(B), and L_(C) are different from each other.

In some embodiments, the compound can have a formula of Pt(L_(A))(L_(B)); and wherein L_(A) and L_(B) can be same or different. In some embodiments, L_(A) and L_(B) can be connected to form a tetradentate ligand.

In some embodiments, L_(B) and L_(C) can be each independently selected from the group consisting of the structures shown below in LIST 3:

wherein: T is selected from the group consisting of B, Al, Ga, and In; each of Y¹ to Y¹³ is independently selected from the group consisting of carbon and nitrogen; Y′ is selected from the group consisting of BR_(e), NR_(e), PR_(e), O, S, Se, C═O, S═O, SO₂, CR_(e)R_(f), SiR_(e)R_(f), and GeR_(e)R_(f); R_(e) and R_(f) can be fused or joined to form a ring; each R_(a), R_(b), R_(c), and R_(d) independently represents zero, mono, or up to a maximum allowed number of substitutions to its associated ring; each of R_(a1), R_(b1), R_(c1), R_(d1), R_(a), R_(b), R_(c), R_(d), R_(e) and R_(f) is independently a hydrogen or a substituent selected from the group consisting of the general substitutents defined herein; and and any two adjacent R_(a), R_(b), R_(c), R_(d), R_(e) and R_(f) can be fused or joined to form a ring or form a multidentate ligand.

In some embodiments, L_(B) and L_(C) can be each independently selected from the group consisting of the structures shown below in LIST 4:

wherein: R_(a)′, R_(b)′, and R_(C)′ each independently represents zero, mono, or up to a maximum allowed substitution to its associated ring; each of R_(a1), R_(b1), R_(c1), R_(a), R_(b), R_(c), R_(N), R_(a)′, R_(b)′, and R_(c)′ is independently hydrogen or a substituent selected from the group consisting of the general substituents defined herein; and two adjacent R_(a)′, R_(b)′, or R_(c)′ can be fused or joined to form a ring or form a multidentate ligand.

In some embodiments, when the compound has formula Ir(L_(Ai-m))₃, i is an integer from 1 to 1560; m is an integer from 1 to 18; and the compound is selected from the group consisting of Ir(L_(A1-1))₃ to Ir(L_(A1560-18))₃;

when the compound has formula Ir(L_(Ai-m′))₃, i is an integer from 1 to 4420; m′ is an integer from 19 to 54; and the compound is selected from the group consisting of Ir(L_(A1-19))₃ to Ir(L_(A4420-54))₃; when the compound has formula Ir(L_(Ai′-m″))₃, i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; and the compound is selected from the group consisting of Ir(L_(A4421-55))₃ to Ir(L_(A4740-69))₃; when the compound has formula Ir(L_(Ai-m))(L_(Bk))₂, i is an integer from 1 to 1560; m is an integer from 1 to 18; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A1-1))(L_(B1))₂ to Ir(L_(A1560-18))(L_(B324))₂; when the compound has formula Ir(L_(Ai-m′))(L_(Bk))₂, i is an integer from 1 to 4420; m′ is an integer from 19 to 54; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A1-19))(L_(B1))₂ to Ir(L_(A4420-54))(L_(B324))₂; when the compound has formula Ir(L_(Ai′-m″))(L_(Bk))₂, i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A4421-55))(L_(B1))₂ to Ir(L_(A4740-69))(L_(B324))₂; when the compound has formula Ir(L_(Ai-m))₂(L_(Bk)), i is an integer from 1 to 1560; m is an integer from 1 to 18; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A1-1))₂(L_(B1)) to Ir(L_(A1560-18))₂(L_(B324)); when the compound has formula Ir(L_(Ai-m′))₂(L_(Bk)), i is an integer from 1 to 4420; m′ is an integer from 19 to 54; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A1-19))₂(L_(B1)) to Ir(L_(A4420-54))₂(L_(B324)); when the compound has formula Ir(L_(Ai′-m″))₂(L_(Bk)), i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A4421-55))₂(L_(B1)) to Ir(L_(A4740-69))₂(L_(B324)); when the compound has formula Ir(L_(Ai-m))₂(L_(Cj-I)), i is an integer from 1 to 1560; m is an integer from 1 to 18; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A1-1))₂(L_(C1-I)) to Ir(L_(A1560-18)) (L_(C1416-I)); when the compound has formula Ir(L_(Ai-m′))₂(L_(Cj-I)), i is an integer from 1 to 4420; m′ is an integer from 19 to 54; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A1-19))₂(L_(C1-I)) to Ir(L_(A4420-54)) (L_(C1416-I)); when the compound has formula Ir(L_(Ai-m″))₂(L_(Cj-I)), i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A4421-55))₂(L_(C1-I)) to Ir(L_(A4740-69)) (L_(C1416-I)); when the compound has formula Ir(L_(Ai-m))₂(L_(Cj-II)), i is an integer from 1 to 1560; m is an integer from 1 to 18; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A1-1))₂(L_(C1-II)) to Ir(L_(A1560-18)) (L_(C1416-II)); when the compound has formula Ir(L_(Ai-m′))₂(L_(Cj-II)), i is an integer from 1 to 4420; m′ is an integer from 19 to 54; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A1-19))₂(L_(C1-II)) to Ir(L_(A4420-54)) (L_(C1416-II)); and when the compound has formula Ir(L_(Ai′-m″))₂(L_(Cj-II)), i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A4421-55))₂(L_(C1-II)) to Ir(L_(A4740-69)) (L_(C1416-II)); wherein the structures of each L_(Ai-m), L_(Ai-m′), and L_(Ai′-m″) are as defined above; wherein each L_(Bk) has the structure defined as follows in LIST 5:

wherein each L_(Cj-I) has a structure based on formula

and each L_(Cj-II) has a structure based on formula

wherein for each L_(Cj) in L_(Cj-I) and L_(Cj-II), R²⁰¹ and R²⁰² are each independently defined as follows in LIST 6:

L_(Cj) R²⁰¹ R²⁰² L_(Cj) R²⁰¹ R²⁰² L_(Cj) R²⁰¹ R²⁰² L_(Cj) R²⁰¹ R²⁰² L_(C1) R^(D1) R^(D1) L_(C193) R^(D1) R^(D3) L_(C385) R^(D17) R^(D40) L_(C577) R^(D143) R^(D120) L_(C2) R^(D2) R^(D2) L_(C194) R^(D1) R^(D4) L_(C386) R^(D17) R^(D41) L_(C578) R^(D143) R^(D133) L_(C3) R^(D3) R^(D3) L_(C195) R^(D1) R^(D5) L_(C387) R^(D17) R^(D42) L_(C579) R^(D143) R^(D134) L_(C4) R^(D4) R^(D4) L_(C196) R^(D1) R^(D9) L_(C388) R^(D17) R^(D43) L_(C580) R^(D143) R^(D135) L_(C5) R^(D5) R^(D5) L_(C197) R^(D1) R^(D10) L_(C389) R^(D17) R^(D48) L_(C581) R^(D143) R^(D136) L_(C6) R^(D6) R^(D6) L_(C198) R^(D1) R^(D17) L_(C390) R^(D17) R^(D49) L_(C582) R^(D143) R^(D144) L_(C7) R^(D7) R^(D7) L_(C199) R^(D1) R^(D18) L_(C391) R^(D17) R^(D50) L_(C583) R^(D143) R^(D145) L_(C8) R^(D8) R^(D8) L_(C200) R^(D1) R^(D20) L_(C392) R^(D17) R^(D54) L_(C584) R^(D143) R^(D146) L_(C9) R^(D9) R^(D9) L_(C201) R^(D1) R^(D22) L_(C393) R^(D17) R^(D55) L_(C585) R^(D143) R^(D147) L_(C10) R^(D10) R^(D10) L_(C202) R^(D1) R^(D37) L_(C394) R^(D17) R^(D58) L_(C586) R^(D143) R^(D149) L_(C11) R^(D11) R^(D11) L_(C203) R^(D1) R^(D40) L_(C395) R^(D17) R^(D59) L_(C587) R^(D143) R^(D151) L_(C12) R^(D12) R^(D12) L_(C204) R^(D1) R^(D41) L_(C396) R^(D17) R^(D78) L_(C588) R^(D143) R^(D154) L_(C13) R^(D13) R^(D13) L_(C205) R^(D1) R^(D42) L_(C397) R^(D17) R^(D79) L_(C589) R^(D143) R^(D155) L_(C14) R^(D14) R^(D14) L_(C206) R^(D1) R^(D43) L_(C398) R^(D17) R^(D81) L_(C590) R^(D143) R^(D161) L_(C15) R^(D15) R^(D15) L_(C207) R^(D1) R^(D48) L_(C399) R^(D17) R^(D87) L_(C591) R^(D143) R^(D175) L_(C16) R^(D16) R^(D16) L_(C208) R^(D1) R^(D49) L_(C400) R^(D17) R^(D88) L_(C592) R^(D144) R^(D3) L_(C17) R^(D17) R^(D17) L_(C209) R^(D1) R^(D50) L_(C401) R^(D17) R^(D89) L_(C593) R^(D144) R^(D5) L_(C18) R^(D18) R^(D18) L_(C210) R^(D1) R^(D54) L_(C402) R^(D17) R^(D93) L_(C594) R^(D144) R^(D17) L_(C19) R^(D19) R^(D19) L_(C211) R^(D1) R^(D55) L_(C403) R^(D17) R^(D116) L_(C595) R^(D144) R^(D18) L_(C20) R^(D20) R^(D20) L_(C212) R^(D1) R^(D58) L_(C404) R^(D17) R^(D117) L_(C596) R^(D144) R^(D20) L_(C21) R^(D21) R^(D21) L_(C213) R^(D1) R^(D59) L_(C405) R^(D17) R^(D118) L_(C597) R^(D144) R^(D22) L_(C22) R^(D22) R^(D22) L_(C214) R^(D1) R^(D78) L_(C406) R^(D17) R^(D119) L_(C598) R^(D144) R^(D37) L_(C23) R^(D23) R^(D23) L_(C215) R^(D1) R^(D79) L_(C407) R^(D17) R^(D120) L_(C599) R^(D144) R^(D40) L_(C24) R^(D24) R^(D24) L_(C216) R^(D1) R^(D81) L_(C408) R^(D17) R^(D133) L_(C600) R^(D144) R^(D41) L_(C25) R^(D25) R^(D25) L_(C217) R^(D1) R^(D87) L_(C409) R^(D17) R^(D134) L_(C601) R^(D144) R^(D42) L_(C26) R^(D26) R^(D26) L_(C218) R^(D1) R^(D88) L_(C410) R^(D17) R^(D135) L_(C602) R^(D144) R^(D43) L_(C27) R^(D27) R^(D27) L_(C219) R^(D1) R^(D89) L_(C411) R^(D17) R^(D136) L_(C603) R^(D144) R^(D48) L_(C28) R^(D28) R^(D28) L_(C220) R^(D1) R^(D93) L_(C412) R^(D17) R^(D143) L_(C604) R^(D144) R^(D49) L_(C29) R^(D29) R^(D29) L_(C221) R^(D1) R^(D116) L_(C413) R^(D17) R^(D144) L_(C605) R^(D144) R^(D54) L_(C30) R^(D30) R^(D30) L_(C222) R^(D1) R^(D117) L_(C414) R^(D17) R^(D145) L_(C606) R^(D144) R^(D58) L_(C31) R^(D31) R^(D31) L_(C223) R^(D1) R^(D118) L_(C415) R^(D17) R^(D146) L_(C607) R^(D144) R^(D59) L_(C32) R^(D32) R^(D32) L_(C224) R^(D1) R^(D119) L_(C416) R^(D17) R^(D147) L_(C608) R^(D144) R^(D78) L_(C33) R^(D33) R^(D33) L_(C225) R^(D1) R^(D120) L_(C417) R^(D17) R^(D149) L_(C609) R^(D144) R^(D79) L_(C34) R^(D34) R^(D34) L_(C226) R^(D1) R^(D133) L_(C418) R^(D17) R^(D151) L_(C610) R^(D144) R^(D81) L_(C35) R^(D35) R^(D35) L_(C227) R^(D1) R^(D134) L_(C419) R^(D17) R^(D154) L_(C611) R^(D144) R^(D87) L_(C36) R^(D36) R^(D36) L_(C228) R^(D1) R^(D135) L_(C420) R^(D17) R^(D155) L_(C612) R^(D144) R^(D88) L_(C37) R^(D37) R^(D37) L_(C229) R^(D1) R^(D136) L_(C421) R^(D17) R^(D161) L_(C613) R^(D144) R^(D89) L_(C38) R^(D38) R^(D38) L_(C230) R^(D1) R^(D143) L_(C422) R^(D17) R^(D175) L_(C614) R^(D144) R^(D93) L_(C39) R^(D39) R^(D39) L_(C231) R^(D1) R^(D144) L_(C423) R^(D50) R^(D3) L_(C615) R^(D144) R^(D116) L_(C40) R^(D40) R^(D40) L_(C232) R^(D1) R^(D145) L_(C424) R^(D50) R^(D5) L_(C616) R^(D144) R^(D117) L_(C41) R^(D41) R^(D41) L_(C233) R^(D1) R^(D146) L_(C425) R^(D50) R^(D18) L_(C617) R^(D144) R^(D118) L_(C42) R^(D42) R^(D42) L_(C234) R^(D1) R^(D147) L_(C426) R^(D50) R^(D20) L_(C618) R^(D144) R^(D119) L_(C43) R^(D43) R^(D43) L_(C235) R^(D1) R^(D149) L_(C427) R^(D50) R^(D22) L_(C619) R^(D144) R^(D120) L_(C44) R^(D44) R^(D44) L_(C236) R^(D1) R^(D151) L_(C428) R^(D50) R^(D37) L_(C620) R^(D144) R^(D133) L_(C45) R^(D45) R^(D45) L_(C237) R^(D1) R^(D154) L_(C429) R^(D50) R^(D40) L_(C621) R^(D144) R^(D134) L_(C46) R^(D46) R^(D46) L_(C238) R^(D1) R^(D155) L_(C430) R^(D50) R^(D41) L_(C622) R^(D144) R^(D135) L_(C47) R^(D47) R^(D47) L_(C239) R^(D1) R^(D161) L_(C431) R^(D50) R^(D42) L_(C623) R^(D144) R^(D136) L_(C48) R^(D48) R^(D48) L_(C240) R^(D1) R^(D175) L_(C432) R^(D50) R^(D43) L_(C624) R^(D144) R^(D145) L_(C49) R^(D49) R^(D49) L_(C241) R^(D4) R^(D3) L_(C433) R^(D50) R^(D48) L_(C625) R^(D144) R^(D146) L_(C50) R^(D50) R^(D50) L_(C242) R^(D4) R^(D5) L_(C434) R^(D50) R^(D49) L_(C626) R^(D144) R^(D147) L_(C51) R^(D51) R^(D51) L_(C243) R^(D4) R^(D9) L_(C435) R^(D50) R^(D54) L_(C627) R^(D144) R^(D149) L_(C52) R^(D52) R^(D52) L_(C244) R^(D4) R^(D10) L_(C436) R^(D50) R^(D55) L_(C628) R^(D144) R^(D151) L_(C53) R^(D55) R^(D55) L_(C245) R^(D4) R^(D17) L_(C437) R^(D50) R^(D58) L_(C629) R^(D144) R^(D154) L_(C54) R^(D54) R^(D54) L_(C246) R^(D4) R^(D18) L_(C438) R^(D50) R^(D59) L_(C630) R^(D144) R^(D155) L_(C55) R^(D55) R^(D55) L_(C247) R^(D4) R^(D20) L_(C439) R^(D50) R^(D78) L_(C631) R^(D144) R^(D161) L_(C56) R^(D56) R^(D56) L_(C248) R^(D4) R^(D22) L_(C440) R^(D50) R^(D79) L_(C632) R^(D144) R^(D175) L_(C57) R^(D57) R^(D57) L_(C249) R^(D4) R^(D37) L_(C441) R^(D50) R^(D81) L_(C633) R^(D145) R^(D3) L_(C58) R^(D58) R^(D58) L_(C250) R^(D4) R^(D40) L_(C442) R^(D50) R^(D87) L_(C634) R^(D145) R^(D5) L_(C59) R^(D59) R^(D59) L_(C251) R^(D4) R^(D41) L_(C443) R^(D50) R^(D88) L_(C635) R^(D145) R^(D17) L_(C60) R^(D60) R^(D60) L_(C252) R^(D4) R^(D42) L_(C444) R^(D50) R^(D89) L_(C636) R^(D145) R^(D18) L_(C61) R^(D61) R^(D61) L_(C253) R^(D4) R^(D43) L_(C445) R^(D50) R^(D93) L_(C637) R^(D145) R^(D20) L_(C62) R^(D62) R^(D62) L_(C254) R^(D4) R^(D48) L_(C446) R^(D50) R^(D116) L_(C638) R^(D145) R^(D22) L_(C63) R^(D63) R^(D63) L_(C255) R^(D4) R^(D49) L_(C447) R^(D50) R^(D117) L_(C639) R^(D145) R^(D37) L_(C64) R^(D64) R^(D64) L_(C256) R^(D4) R^(D50) L_(C448) R^(D50) R^(D118) L_(C640) R^(D145) R^(D40) L_(C65) R^(D65) R^(D65) L_(C257) R^(D4) R^(D54) L_(C449) R^(D50) R^(D119) L_(C641) R^(D145) R^(D41) L_(C66) R^(D66) R^(D66) L_(C258) R^(D4) R^(D55) L_(C450) R^(D50) R^(D120) L_(C642) R^(D145) R^(D42) L_(C67) R^(D67) R^(D67) L_(C259) R^(D4) R^(D58) L_(C451) R^(D50) R^(D133) L_(C643) R^(D145) R^(D43) L_(C68) R^(D68) R^(D68) L_(C260) R^(D4) R^(D59) L_(C452) R^(D50) R^(D134) L_(C644) R^(D145) R^(D48) L_(C69) R^(D69) R^(D69) L_(C261) R^(D4) R^(D78) L_(C453) R^(D50) R^(D135) L_(C645) R^(D145) R^(D49) L_(C70) R^(D70) R^(D70) L_(C262) R^(D4) R^(D79) L_(C454) R^(D50) R^(D136) L_(C646) R^(D145) R^(D54) L_(C71) R^(D71) R^(D71) L_(C263) R^(D4) R^(D81) L_(C455) R^(D50) R^(D143) L_(C647) R^(D145) R^(D58) L_(C72) R^(D72) R^(D72) L_(C264) R^(D4) R^(D87) L_(C456) R^(D50) R^(D144) L_(C648) R^(D145) R^(D59) L_(C73) R^(D73) R^(D73) L_(C265) R^(D4) R^(D88) L_(C457) R^(D50) R^(D145) L_(C649) R^(D145) R^(D78) L_(C74) R^(D74) R^(D74) L_(C266) R^(D4) R^(D89) L_(C458) R^(D50) R^(D146) L_(C650) R^(D145) R^(D79) L_(C75) R^(D75) R^(D75) L_(C267) R^(D4) R^(D93) L_(C459) R^(D50) R^(D147) L_(C651) R^(D145) R^(D81) L_(C76) R^(D76) R^(D76) L_(C268) R^(D4) R^(D116) L_(C460) R^(D50) R^(D149) L_(C652) R^(D145) R^(D87) L_(C77) R^(D77) R^(D77) L_(C269) R^(D4) R^(D117) L_(C461) R^(D50) R^(D151) L_(C653) R^(D145) R^(D88) L_(C78) R^(D78) R^(D78) L_(C270) R^(D4) R^(D118) L_(C462) R^(D50) R^(D154) L_(C654) R^(D145) R^(D89) L_(C79) R^(D79) R^(D79) L_(C271) R^(D4) R^(D119) L_(C463) R^(D50) R^(D155) L_(C655) R^(D145) R^(D93) L_(C80) R^(D80) R^(D80) L_(C272) R^(D4) R^(D120) L_(C464) R^(D50) R^(D161) L_(C656) R^(D145) R^(D116) L_(C81) R^(D81) R^(D81) L_(C273) R^(D4) R^(D133) L_(C465) R^(D50) R^(D175) L_(C657) R^(D145) R^(D117) L_(C82) R^(D82) R^(D82) L_(C274) R^(D4) R^(D134) L_(C466) R^(D55) R^(D3) L_(C658) R^(D145) R^(D118) L_(C83) R^(D83) R^(D83) L_(C275) R^(D4) R^(D135) L_(C467) R^(D55) R^(D5) L_(C659) R^(D145) R^(D119) L_(C84) R^(D84) R^(D84) L_(C276) R^(D4) R^(D136) L_(C468) R^(D55) R^(D18) L_(C660) R^(D145) R^(D120) L_(C85) R^(D85) R^(D85) L_(C277) R^(D4) R^(D143) L_(C469) R^(D55) R^(D20) L_(C661) R^(D145) R^(D133) L_(C86) R^(D86) R^(D86) L_(C278) R^(D4) R^(D144) L_(C470) R^(D55) R^(D22) L_(C662) R^(D145) R^(D134) L_(C87) R^(D87) R^(D87) L_(C279) R^(D4) R^(D145) L_(C471) R^(D55) R^(D37) L_(C663) R^(D145) R^(D135) L_(C88) R^(D88) R^(D88) L_(C280) R^(D4) R^(D146) L_(C472) R^(D55) R^(D40) L_(C664) R^(D145) R^(D136) L_(C89) R^(D89) R^(D89) L_(C281) R^(D4) R^(D147) L_(C473) R^(D55) R^(D41) L_(C665) R^(D145) R^(D146) L_(C90) R^(D90) R^(D90) L_(C282) R^(D4) R^(D149) L_(C474) R^(D55) R^(D42) L_(C666) R^(D145) R^(D147) L_(C91) R^(D91) R^(D91) L_(C283) R^(D4) R^(D151) L_(C475) R^(D55) R^(D43) L_(C667) R^(D145) R^(D149) L_(C92) R^(D92) R^(D92) L_(C284) R^(D4) R^(D154) L_(C476) R^(D55) R^(D48) L_(C668) R^(D145) R^(D151) L_(C93) R^(D93) R^(D93) L_(C285) R^(D4) R^(D155) L_(C477) R^(D55) R^(D49) L_(C669) R^(D145) R^(D154) L_(C94) R^(D94) R^(D94) L_(C286) R^(D4) R^(D161) L_(C478) R^(D55) R^(D54) L_(C670) R^(D145) R^(D155) L_(C95) R^(D95) R^(D95) L_(C287) R^(D4) R^(D175) L_(C479) R^(D55) R^(D58) L_(C671) R^(D145) R^(D161) L_(C96) R^(D96) R^(D96) L_(C288) R^(D9) R^(D3) L_(C480) R^(D55) R^(D59) L_(C672) R^(D145) R^(D175) L_(C97) R^(D97) R^(D97) L_(C289) R^(D9) R^(D5) L_(C481) R^(D55) R^(D78) L_(C673) R^(D146) R^(D3) L_(C98) R^(D98) R^(D98) L_(C290) R^(D9) R^(D10) L_(C482) R^(D55) R^(D79) L_(C674) R^(D146) R^(D5) L_(C99) R^(D99) R^(D99) L_(C291) R^(D9) R^(D17) L_(C483) R^(D55) R^(D81) L_(C675) R^(D146) R^(D17) L_(C100) R^(D100) R^(D100) L_(C292) R^(D9) R^(D18) L_(C484) R^(D55) R^(D87) L_(C676) R^(D146) R^(D18) L_(C101) R^(D101) R^(D101) L_(C293) R^(D9) R^(D20) L_(C485) R^(D55) R^(D88) L_(C677) R^(D146) R^(D20) L_(C102) R^(D102) R^(D102) L_(C294) R^(D9) R^(D22) L_(C486) R^(D55) R^(D89) L_(C678) R^(D146) R^(D22) L_(C103) R^(D103) R^(D103) L_(C295) R^(D9) R^(D37) L_(C487) R^(D55) R^(D93) L_(C679) R^(D146) R^(D37) L_(C104) R^(D104) R^(D104) L_(C296) R^(D9) R^(D40) L_(C488) R^(D55) R^(D116) L_(C680) R^(D146) R^(D40) L_(C105) R^(D105) R^(D105) L_(C297) R^(D9) R^(D41) L_(C489) R^(D55) R^(D117) L_(C681) R^(D146) R^(D41) L_(C106) R^(D106) R^(D106) L_(C298) R^(D9) R^(D42) L_(C490) R^(D55) R^(D118) L_(C682) R^(D146) R^(D42) L_(C107) R^(D107) R^(D107) L_(C299) R^(D9) R^(D43) L_(C491) R^(D55) R^(D119) L_(C683) R^(D146) R^(D43) L_(C108) R^(D108) R^(D108) L_(C300) R^(D9) R^(D48) L_(C492) R^(D55) R^(D120) L_(C684) R^(D146) R^(D48) L_(C109) R^(D109) R^(D109) L_(C301) R^(D9) R^(D49) L_(C493) R^(D55) R^(D133) L_(C685) R^(D146) R^(D49) L_(C110) R^(D110) R^(D110) L_(C302) R^(D9) R^(D50) L_(C494) R^(D55) R^(D134) L_(C686) R^(D146) R^(D54) L_(C111) R^(D111) R^(D111) L_(C303) R^(D9) R^(D54) L_(C495) R^(D55) R^(D135) L_(C687) R^(D146) R^(D58) L_(C112) R^(D112) R^(D112) L_(C304) R^(D9) R^(D55) L_(C496) R^(D55) R^(D136) L_(C688) R^(D146) R^(D59) L_(C113) R^(D113) R^(D113) L_(C305) R^(D9) R^(D58) L_(C497) R^(D55) R^(D143) L_(C689) R^(D146) R^(D78) L_(C114) R^(D114) R^(D114) L_(C306) R^(D9) R^(D59) L_(C498) R^(D55) R^(D144) L_(C690) R^(D146) R^(D79) L_(C115) R^(D115) R^(D115) L_(C307) R^(D9) R^(D78) L_(C499) R^(D55) R^(D145) L_(C691) R^(D146) R^(D81) L_(C116) R^(D116) R^(D116) L_(C308) R^(D9) R^(D79) L_(C500) R^(D55) R^(D146) L_(C692) R^(D146) R^(D87) L_(C117) R^(D117) R^(D117) L_(C309) R^(D9) R^(D81) L_(C501) R^(D55) R^(D147) L_(C693) R^(D146) R^(D88) L_(C118) R^(D118) R^(D118) L_(C310) R^(D9) R^(D87) L_(C502) R^(D55) R^(D149) L_(C694) R^(D146) R^(D89) L_(C119) R^(D119) R^(D119) L_(C311) R^(D9) R^(D88) L_(C503) R^(D55) R^(D151) L_(C695) R^(D146) R^(D93) L_(C120) R^(D120) R^(D120) L_(C312) R^(D9) R^(D89) L_(C504) R^(D55) R^(D154) L_(C696) R^(D146) R^(D117) L_(C121) R^(D121) R^(D121) L_(C313) R^(D9) R^(D93) L_(C505) R^(D55) R^(D155) L_(C697) R^(D146) R^(D118) L_(C122) R^(D122) R^(D122) L_(C314) R^(D9) R^(D116) L_(C506) R^(D55) R^(D161) L_(C698) R^(D146) R^(D119) L_(C123) R^(D123) R^(D123) L_(C315) R^(D9) R^(D117) L_(C507) R^(D55) R^(D175) L_(C699) R^(D146) R^(D120) L_(C124) R^(D124) R^(D124) L_(C316) R^(D9) R^(D118) L_(C508) R^(D116) R^(D3) L_(C700) R^(D146) R^(D133) L_(C125) R^(D125) R^(D125) L_(C317) R^(D9) R^(D119) L_(C509) R^(D116) R^(D5) L_(C701) R^(D146) R^(D134) L_(C126) R^(D126) R^(D126) L_(C318) R^(D9) R^(D120) L_(C510) R^(D116) R^(D17) L_(C702) R^(D146) R^(D135) L_(C127) R^(D127) R^(D127) L_(C319) R^(D9) R^(D133) L_(C511) R^(D116) R^(D18) L_(C703) R^(D146) R^(D136) L_(C128) R^(D128) R^(D128) L_(C320) R^(D9) R^(D134) L_(C512) R^(D116) R^(D20) L_(C704) R^(D146) R^(D146) L_(C129) R^(D129) R^(D129) L_(C321) R^(D9) R^(D135) L_(C513) R^(D116) R^(D22) L_(C705) R^(D146) R^(D147) L_(C130) R^(D130) R^(D130) L_(C322) R^(D9) R^(D136) L_(C514) R^(D116) R^(D37) L_(C706) R^(D146) R^(D149) L_(C131) R^(D131) R^(D131) L_(C323) R^(D9) R^(D143) L_(C515) R^(D116) R^(D40) L_(C707) R^(D146) R^(D151) L_(C132) R^(D132) R^(D132) L_(C324) R^(D9) R^(D144) L_(C516) R^(D116) R^(D41) L_(C708) R^(D146) R^(D154) L_(C133) R^(D133) R^(D133) L_(C325) R^(D9) R^(D145) L_(C517) R^(D116) R^(D42) L_(C709) R^(D146) R^(D155) L_(C134) R^(D134) R^(D134) L_(C326) R^(D9) R^(D146) L_(C518) R^(D116) R^(D43) L_(C710) R^(D146) R^(D161) L_(C135) R^(D135) R^(D135) L_(C327) R^(D9) R^(D147) L_(C519) R^(D116) R^(D48) L_(C711) R^(D146) R^(D175) L_(C136) R^(D136) R^(D136) L_(C328) R^(D9) R^(D149) L_(C520) R^(D116) R^(D49) L_(C712) R^(D133) R^(D3) L_(C137) R^(D137) R^(D137) L_(C329) R^(D9) R^(D151) L_(C521) R^(D116) R^(D54) L_(C713) R^(D133) R^(D5) L_(C138) R^(D138) R^(D138) L_(C330) R^(D9) R^(D154) L_(C522) R^(D116) R^(D58) L_(C714) R^(D133) R^(D3) L_(C139) R^(D139) R^(D139) L_(C331) R^(D9) R^(D155) L_(C523) R^(D116) R^(D59) L_(C715) R^(D133) R^(D18) L_(C140) R^(D140) R^(D140) L_(C332) R^(D9) R^(D161) L_(C524) R^(D116) R^(D78) L_(C716) R^(D133) R^(D20) L_(C141) R^(D141) R^(D141) L_(C333) R^(D9) R^(D175) L_(C525) R^(D116) R^(D79) L_(C717) R^(D133) R^(D22) L_(C142) R^(D142) R^(D142) L_(C334) R^(D10) R^(D3) L_(C526) R^(D116) R^(D81) L_(C718) R^(D133) R^(D37) L_(C143) R^(D143) R^(D143) L_(C335) R^(D10) R^(D5) L_(C527) R^(D116) R^(D87) L_(C719) R^(D133) R^(D40) L_(C144) R^(D144) R^(D144) L_(C336) R^(D10) R^(D17) L_(C528) R^(D116) R^(D88) L_(C720) R^(D133) R^(D41) L_(C145) R^(D145) R^(D145) L_(C337) R^(D10) R^(D18) L_(C529) R^(D116) R^(D89) L_(C721) R^(D133) R^(D42) L_(C146) R^(D146) R^(D146) L_(C338) R^(D10) R^(D20) L_(C530) R^(D116) R^(D95) L_(C722) R^(D133) R^(D43) L_(C147) R^(D147) R^(D147) L_(C339) R^(D10) R^(D22) L_(C531) R^(D116) R^(D117) L_(C723) R^(D133) R^(D48) L_(C148) R^(D148) R^(D148) L_(C340) R^(D10) R^(D37) L_(C532) R^(D116) R^(D118) L_(C724) R^(D133) R^(D49) L_(C149) R^(D149) R^(D149) L_(C341) R^(D10) R^(D40) L_(C533) R^(D116) R^(D119) L_(C725) R^(D133) R^(D54) L_(C150) R^(D150) R^(D150) L_(C342) R^(D10) R^(D41) L_(C534) R^(D116) R^(D120) L_(C726) R^(D133) R^(D58) L_(C151) R^(D151) R^(D151) L_(C343) R^(D10) R^(D42) L_(C535) R^(D116) R^(D133) L_(C727) R^(D133) R^(D59) L_(C152) R^(D152) R^(D152) L_(C344) R^(D10) R^(D43) L_(C536) R^(D116) R^(D134) L_(C728) R^(D133) R^(D78) L_(C153) R^(D153) R^(D153) L_(C345) R^(D10) R^(D48) L_(C537) R^(D116) R^(D135) L_(C729) R^(D133) R^(D79) L_(C154) R^(D154) R^(D154) L_(C346) R^(D10) R^(D49) L_(C538) R^(D116) R^(D136) L_(C730) R^(D133) R^(D81) L_(C155) R^(D155) R^(D155) L_(C347) R^(D10) R^(D50) L_(C539) R^(D116) R^(D143) L_(C731) R^(D133) R^(D87) L_(C156) R^(D 156) R^(D156) L_(C348) R^(D10) R^(D54) L_(C540) R^(D116) R^(D144) L_(C732) R^(D133) R^(D88) L_(C157) R^(D157) R^(D157) L_(C349) R^(D10) R^(D55) L_(C541) R^(D116) R^(D145) L_(C733) R^(D133) R^(D89) L_(C158) R^(D158) R^(D158) L_(C350) R^(D10) R^(D58) L_(C542) R^(D116) R^(D146) L_(C734) R^(D133) R^(D93) L_(C159) R^(D159) R^(D159) L_(C351) R^(D10) R^(D59) L_(C543) R^(D116) R^(D147) L_(C735) R^(D133) R^(D117) L_(C160) R^(D160) R^(D160) L_(C352) R^(D10) R^(D78) L_(C544) R^(D116) R^(D149) L_(C736) R^(D133) R^(D118) L_(C161) R^(D161) R^(D161) L_(C353) R^(D10) R^(D79) L_(C545) R^(D116) R^(D151) L_(C737) R^(D133) R^(D119) L_(C162) R^(D162) R^(D162) L_(C354) R^(D10) R^(D81) L_(C546) R^(D116) R^(D154) L_(C738) R^(D133) R^(D120) L_(C163) R^(D163) R^(D163) L_(C355) R^(D10) R^(D87) L_(C547) R^(D116) R^(D155) L_(C739) R^(D133) R^(D133) L_(C164) R^(D164) R^(D164) L_(C356) R^(D10) R^(D88) L_(C548) R^(D116) R^(D161) L_(C740) R^(D133) R^(D134) L_(C165) R^(D165) R^(D165) L_(C357) R^(D10) R^(D89) L_(C549) R^(D116) R^(D175) L_(C741) R^(D133) R^(D135) L_(C166) R^(D166) R^(D166) L_(C358) R^(D10) R^(D93) L_(C550) R^(D143) R^(D3) L_(C742) R^(D133) R^(D136) L_(C167) R^(D167) R^(D167) L_(C359) R^(D10) R^(D116) L_(C551) R^(D143) R^(D5) L_(C743) R^(D133) R^(D146) L_(C168) R^(D168) R^(D168) L_(C360) R^(D10) R^(D117) L_(C552) R^(D143) R^(D17) L_(C744) R^(D133) R^(D147) L_(C169) R^(D169) R^(D169) L_(C361) R^(D10) R^(D118) L_(C553) R^(D143) R^(D18) L_(C745) R^(D133) R^(D149) L_(C170) R^(D170) R^(D170) L_(C362) R^(D10) R^(D119) L_(C554) R^(D143) R^(D20) L_(C746) R^(D133) R^(D151) L_(C171) R^(D171) R^(D171) L_(C363) R^(D10) R^(D120) L_(C555) R^(D143) R^(D22) L_(C747) R^(D133) R^(D154) L_(C172) R^(D172) R^(D172) L_(C364) R^(D10) R^(D133) L_(C556) R^(D143) R^(D37) L_(C748) R^(D133) R^(D155) L_(C173) R^(D173) R^(D173) L_(C365) R^(D10) R^(D134) L_(C557) R^(D143) R^(D40) L_(C749) R^(D133) R^(D161) L_(C174) R^(D174) R^(D174) L_(C366) R^(D10) R^(D135) L_(C558) R^(D143) R^(D41) L_(C750) R^(D133) R^(D175) L_(C175) R^(D175) R^(D175) L_(C367) R^(D10) R^(D136) L_(C559) R^(D143) R^(D42) L_(C751) R^(D175) R^(D3) L_(C176) R^(D176) R^(D176) L_(C368) R^(D10) R^(D143) L_(C560) R^(D143) R^(D43) L_(C752) R^(D175) R^(D5) L_(C177) R^(D177) R^(D177) L_(C369) R^(D10) R^(D144) L_(C561) R^(D143) R^(D48) L_(C753) R^(D175) R^(D18) L_(C178) R^(D178) R^(D178) L_(C370) R^(D10) R^(D145) L_(C562) R^(D143) R^(D49) L_(C754) R^(D175) R^(D20) L_(C179) R^(D179) R^(D179) L_(C371) R^(D10) R^(D146) L_(C563) R^(D143) R^(D54) L_(C755) R^(D175) R^(D22) L_(C180) R^(D180) R^(D180) L_(C372) R^(D10) R^(D147) L_(C564) R^(D143) R^(D58) L_(C756) R^(D175) R^(D37) L_(C181) R^(D181) R^(D181) L_(C373) R^(D10) R^(D149) L_(C565) R^(D143) R^(D59) L_(C757) R^(D175) R^(D40) L_(C182) R^(D182) R^(D182) L_(C374) R^(D10) R^(D151) L_(C566) R^(D143) R^(D78) L_(C758) R^(D175) R^(D41) L_(C183) R^(D183) R^(D183) L_(C375) R^(D10) R^(D154) L_(C567) R^(D143) R^(D79) L_(C759) R^(D175) R^(D42) L_(C184) R^(D184) R^(D184) L_(C376) R^(D10) R^(D155) L_(C568) R^(D143) R^(D81) L_(C760) R^(D175) R^(D43) L_(C185) R^(D185) R^(D185) L_(C377) R^(D10) R^(D161) L_(C569) R^(D143) R^(D87) L_(C761) R^(D175) R^(D48) L_(C186) R^(D186) R^(D186) L_(C378) R^(D10) R^(D175) L_(C570) R^(D143) R^(D88) L_(C762) R^(D175) R^(D49) L_(C187) R^(D187) R^(D187) L_(C379) R^(D17) R^(D3) L_(C571) R^(D143) R^(D89) L_(C763) R^(D175) R^(D54) L_(C188) R^(D188) R^(D188) L_(C380) R^(D17) R^(D5) L_(C572) R^(D143) R^(D93) L_(C764) R^(D175) R^(D58) L_(C189) R^(D189) R^(D189) L_(C381) R^(D17) R^(D18) L_(C573) R^(D143) R^(D116) L_(C765) R^(D175) R^(D59) L_(C190) R^(D190) R^(D190) L_(C382) R^(D17) R^(D20) L_(C574) R^(D143) R^(D117) L_(C766) R^(D175) R^(D78) L_(C191) R^(D191) R^(D191) L_(C383) R^(D17) R^(D22) L_(C575) R^(D143) R^(D118) L_(C767) R^(D175) R^(D79) L_(C192) R^(D192) R^(D192) L_(C384) R^(D17) R^(D37) L_(C576) R^(D143) R^(D119) L_(C768) R^(D175) R^(D81) L_(C769) R^(D193) R^(D193) L_(C877) R^(D1) R^(D193) L_(C985) R^(D4) R^(D193) L_(C1093) R^(D9) R^(D193) L_(C770) R^(D194) R^(D194) L_(C878) R^(D1) R^(D194) L_(C986) R^(D4) R^(D194) L_(C1094) R^(D9) R^(D194) L_(C771) R^(D195) R^(D195) L_(C879) R^(D1) R^(D195) L_(C987) R^(D4) R^(D195) L_(C1095) R^(D9) R^(D195) L_(C772) R^(D196) R^(D196) L_(C880) R^(D1) R^(D196) L_(C988) R^(D4) R^(D196) L_(C1096) R^(D9) R^(D196) L_(C773) R^(D197) R^(D197) L_(C881) R^(D1) R^(D197) L_(C989) R^(D4) R^(D197) L_(C1097) R^(D9) R^(D197) L_(C774) R^(D198) R^(D198) L_(C882) R^(D1) R^(D198) L_(C990) R^(D4) R^(D198) L_(C1098) R^(D9) R^(D198) L_(C775) R^(D199) R^(D199) L_(C883) R^(D1) R^(D199) L_(C991) R^(D4) R^(D199) L_(C1099) R^(D9) R^(D199) L_(C776) R^(D200) R^(D200) L_(C884) R^(D1) R^(D200) L_(C992) R^(D4) R^(D200) L_(C1100) R^(D9) R^(D200) L_(C777) R^(D201) R^(D201) L_(C885) R^(D1) R^(D201) L_(C993) R^(D4) R^(D201) L_(C1101) R^(D9) R^(D201) L_(C778) R^(D202) R^(D202) L_(C886) R^(D1) R^(D202) L_(C994) R^(D4) R^(D202) L_(C1102) R^(D9) R^(D202) L_(C779) R^(D203) R^(D203) L_(C887) R^(D1) R^(D203) L_(C995) R^(D4) R^(D203) L_(C1103) R^(D9) R^(D203) L_(C780) R^(D204) R^(D204) L_(C888) R^(D1) R^(D204) L_(C996) R^(D4) R^(D204) L_(C1104) R^(D9) R^(D204) L_(C781) R^(D205) R^(D205) L_(C889) R^(D1) R^(D205) L_(C997) R^(D4) R^(D205) L_(C1105) R^(D9) R^(D205) L_(C782) R^(D206) R^(D206) L_(C890) R^(D1) R^(D206) L_(C998) R^(D4) R^(D206) L_(C1106) R^(D9) R^(D206) L_(C783) R^(D207) R^(D207) L_(C891) R^(D1) R^(D207) L_(C999) R^(D4) R^(D207) L_(C1107) R^(D9) R^(D207) L_(C784) R^(D208) R^(D208) L_(C892) R^(D1) R^(D208) L_(C1000) R^(D4) R^(D208) L_(C1108) R^(D9) R^(D208) L_(C785) R^(D209) R^(D209) L_(C893) R^(D1) R^(D209) L_(C1001) R^(D4) R^(D209) L_(C1109) R^(D9) R^(D209) L_(C786) R^(D210) R^(D210) L_(C894) R^(D1) R^(D210) L_(C1002) R^(D4) R^(D210) L_(C1110) R^(D9) R^(D210) L_(C787) R^(D211) R^(D211) L_(C895) R^(D1) R^(D211) L_(C1003) R^(D4) R^(D211) L_(C1111) R^(D9) R^(D211) L_(C788) R^(D212) R^(D212) L_(C896) R^(D1) R^(D212) L_(C1004) R^(D4) R^(D212) L_(C1112) R^(D9) R^(D212) L_(C789) R^(D213) R^(D213) L_(C897) R^(D1) R^(D213) L_(C1005) R^(D4) R^(D213) L_(C1113) R^(D9) R^(D213) L_(C790) R^(D214) R^(D214) L_(C898) R^(D1) R^(D214) L_(C1006) R^(D4) R^(D214) L_(C1114) R^(D9) R^(D214) L_(C791) R^(D215) R^(D215) L_(C899) R^(D1) R^(D215) L_(C1007) R^(D4) R^(D215) L_(C1115) R^(D9) R^(D215) L_(C792) R^(D216) R^(D216) L_(C900) R^(D1) R^(D216) L_(C1008) R^(D4) R^(D216) L_(C1116) R^(D9) R^(D216) L_(C793) R^(D217) R^(D217) L_(C901) R^(D1) R^(D217) L_(C1009) R^(D4) R^(D217) L_(C1117) R^(D9) R^(D217) L_(C794) R^(D218) R^(D218) L_(C902) R^(D1) R^(D218) L_(C1010) R^(D4) R^(D218) L_(C1118) R^(D9) R^(D218) L_(C795) R^(D219) R^(D219) L_(C903) R^(D1) R^(D219) L_(C1011) R^(D4) R^(D219) L_(C1119) R^(D9) R^(D219) L_(C796) R^(D220) R^(D220) L_(C904) R^(D1) R^(D220) L_(C1012) R^(D4) R^(D220) L_(C1120) R^(D9) R^(D220) L_(C797) R^(D221) R^(D221) L_(C905) R^(D1) R^(D221) L_(C1013) R^(D4) R^(D221) L_(C1121) R^(D9) R^(D221) L_(C798) R^(D222) R^(D222) L_(C906) R^(D1) R^(D222) L_(C1014) R^(D4) R^(D222) L_(C1122) R^(D9) R^(D222) L_(C799) R^(D223) R^(D223) L_(C907) R^(D1) R^(D223) L_(C1015) R^(D4) R^(D223) L_(C1123) R^(D9) R^(D223) L_(C800) R^(D224) R^(D224) L_(C908) R^(D1) R^(D224) L_(C1016) R^(D4) R^(D224) L_(C1124) R^(D9) R^(D224) L_(C801) R^(D225) R^(D225) L_(C909) R^(D1) R^(D225) L_(C1017) R^(D4) R^(D225) L_(C1125) R^(D9) R^(D225) L_(C802) R^(D226) R^(D226) L_(C910) R^(D1) R^(D226) L_(C1018) R^(D4) R^(D226) L_(C1126) R^(D9) R^(D226) L_(C803) R^(D227) R^(D227) L_(C911) R^(D1) R^(D227) L_(C1019) R^(D4) R^(D227) L_(C1127) R^(D9) R^(D227) L_(C804) R^(D228) R^(D228) L_(C912) R^(D1) R^(D228) L_(C1020) R^(D4) R^(D228) L_(C1128) R^(D9) R^(D228) L_(C805) R^(D229) R^(D229) L_(C913) R^(D1) R^(D229) L_(C1021) R^(D4) R^(D229) L_(C1129) R^(D9) R^(D229) L_(C806) R^(D230) R^(D230) L_(C914) R^(D1) R^(D230) L_(C1022) R^(D4) R^(D230) L_(C1130) R^(D9) R^(D230) L_(C807) R^(D231) R^(D231) L_(C915) R^(D1) R^(D231) L_(C1023) R^(D4) R^(D231) L_(C1131) R^(D9) R^(D231) L_(C808) R^(D232) R^(D232) L_(C916) R^(D1) R^(D232) L_(C1024) R^(D4) R^(D232) L_(C1132) R^(D9) R^(D232) L_(C809) R^(D233) R^(D233) L_(C917) R^(D1) R^(D233) L_(C1025) R^(D4) R^(D233) L_(C1133) R^(D9) R^(D233) L_(C810) R^(D234) R^(D234) L_(C918) R^(D1) R^(D234) L_(C1026) R^(D4) R^(D234) L_(C1134) R^(D9) R^(D234) L_(C811) R^(D235) R^(D235) L_(C919) R^(D1) R^(D235) L_(C1027) R^(D4) R^(D235) L_(C1135) R^(D9) R^(D235) L_(C812) R^(D236) R^(D236) L_(C920) R^(D1) R^(D236) L_(C1028) R^(D4) R^(D236) L_(C1136) R^(D9) R^(D236) L_(C813) R^(D237) R^(D237) L_(C921) R^(D1) R^(D237) L_(C1029) R^(D4) R^(D237) L_(C1137) R^(D9) R^(D237) L_(C814) R^(D238) R^(D238) L_(C922) R^(D1) R^(D238) L_(C1030) R^(D4) R^(D238) L_(C1138) R^(D9) R^(D238) L_(C815) R^(D239) R^(D239) L_(C923) R^(D1) R^(D239) L_(C1031) R^(D4) R^(D239) L_(C1139) R^(D9) R^(D239) L_(C816) R^(D240) R^(D240) L_(C924) R^(D1) R^(D240) L_(C1032) R^(D4) R^(D240) L_(C1140) R^(D9) R^(D240) L_(C817) R^(D241) R^(D241) L_(C925) R^(D1) R^(D241) L_(C1033) R^(D4) R^(D241) L_(C1141) R^(D9) R^(D241) L_(C818) R^(D242) R^(D242) L_(C926) R^(D1) R^(D242) L_(C1034) R^(D4) R^(D242) L_(C1142) R^(D9) R^(D242) L_(C819) R^(D243) R^(D243) L_(C927) R^(D1) R^(D243) L_(C1035) R^(D4) R^(D243) L_(C1143) R^(D9) R^(D243) L_(C820) R^(D244) R^(D244) L_(C928) R^(D1) R^(D244) L_(C1036) R^(D4) R^(D244) L_(C1144) R^(D9) R^(D244) L_(C821) R^(D245) R^(D245) L_(C929) R^(D1) R^(D245) L_(C1037) R^(D4) R^(D245) L_(C1145) R^(D9) R^(D245) L_(C822) R^(D246) R^(D246) L_(C930) R^(D1) R^(D246) L_(C1038) R^(D4) R^(D246) L_(C1146) R^(D9) R^(D246) L_(C823) R^(D17) R^(D193) L_(C931) R^(D50) R^(D193) L_(C1039) R^(D145) R^(D193) L_(C1147) R^(D168) R^(D193) L_(C824) R^(D17) R^(D194) L_(C932) R^(D50) R^(D194) L_(C1040) R^(D145) R^(D194) L_(C1148) R^(D168) R^(D194) L_(C825) R^(D17) R^(D195) L_(C933) R^(D50) R^(D195) L_(C1041) R^(D145) R^(D195) L_(C1149) R^(D168) R^(D195) L_(C826) R^(D17) R^(D196) L_(C934) R^(D50) R^(D196) L_(C1042) R^(D145) R^(D196) L_(C1150) R^(D168) R^(D196) L_(C827) R^(D17) R^(D197) L_(C935) R^(D50) R^(D197) L_(C1043) R^(D145) R^(D197) L_(C1151) R^(D168) R^(D197) L_(C828) R^(D17) R^(D198) L_(C936) R^(D50) R^(D198) L_(C1044) R^(D145) R^(D198) L_(C1152) R^(D168) R^(D198) L_(C829) R^(D17) R^(D199) L_(C937) R^(D50) R^(D199) L_(C1045) R^(D145) R^(D199) L_(C1153) R^(D168) R^(D199) L_(C830) R^(D17) R^(D200) L_(C938) R^(D50) R^(D200) L_(C1046) R^(D145) R^(D200) L_(C1154) R^(D168) R^(D200) L_(C831) R^(D17) R^(D201) L_(C939) R^(D50) R^(D201) L_(C1047) R^(D145) R^(D201) L_(C1155) R^(D168) R^(D201) L_(C832) R^(D17) R^(D202) L_(C940) R^(D50) R^(D202) L_(C1048) R^(D145) R^(D202) L_(C1156) R^(D168) R^(D202) L_(C833) R^(D17) R^(D203) L_(C941) R^(D50) R^(D203) L_(C1049) R^(D145) R^(D203) L_(C1157) R^(D168) R^(D203) L_(C834) R^(D17) R^(D204) L_(C942) R^(D50) R^(D204) L_(C1050) R^(D145) R^(D204) L_(C1158) R^(D168) R^(D204) L_(C835) R^(D17) R^(D205) L_(C943) R^(D50) R^(D205) L_(C1051) R^(D145) R^(D205) L_(C1159) R^(D168) R^(D205) L_(C836) R^(D17) R^(D206) L_(C944) R^(D50) R^(D206) L_(C1052) R^(D145) R^(D206) L_(C1160) R^(D168) R^(D206) L_(C837) R^(D17) R^(D207) L_(C945) R^(D50) R^(D207) L_(C1053) R^(D145) R^(D207) L_(C1161) R^(D168) R^(D207) L_(C838) R^(D17) R^(D208) L_(C946) R^(D50) R^(D208) L_(C1054) R^(D145) R^(D208) L_(C1162) R^(D168) R^(D208) L_(C839) R^(D17) R^(D209) L_(C947) R^(D50) R^(D209) L_(C1055) R^(D145) R^(D209) L_(C1163) R^(D168) R^(D209) L_(C840) R^(D17) R^(D210) L_(C948) R^(D50) R^(D210) L_(C1056) R^(D145) R^(D210) L_(C1164) R^(D168) R^(D210) L_(C841) R^(D17) R^(D211) L_(C949) R^(D50) R^(D211) L_(C1057) R^(D145) R^(D211) L_(C1165) R^(D168) R^(D211) L_(C842) R^(D17) R^(D212) L_(C950) R^(D50) R^(D212) L_(C1058) R^(D145) R^(D212) L_(C1166) R^(D168) R^(D212) L_(C843) R^(D17) R^(D213) L_(C951) R^(D50) R^(D213) L_(C1059) R^(D145) R^(D213) L_(C1167) R^(D168) R^(D213) L_(C844) R^(D17) R^(D214) L_(C952) R^(D50) R^(D214) L_(C1060) R^(D145) R^(D214) L_(C1168) R^(D168) R^(D214) L_(C845) R^(D17) R^(D215) L_(C953) R^(D50) R^(D215) L_(C1061) R^(D145) R^(D215) L_(C1169) R^(D168) R^(D215) L_(C846) R^(D17) R^(D216) L_(C954) R^(D50) R^(D216) L_(C1062) R^(D145) R^(D216) L_(C1170) R^(D168) R^(D216) L_(C847) R^(D17) R^(D217) L_(C955) R^(D50) R^(D217) L_(C1063) R^(D145) R^(D217) L_(C1171) R^(D168) R^(D217) L_(C848) R^(D17) R^(D218) L_(C956) R^(D50) R^(D218) L_(C1064) R^(D145) R^(D218) L_(C1172) R^(D168) R^(D218) L_(C849) R^(D17) R^(D219) L_(C957) R^(D50) R^(D219) L_(C1065) R^(D145) R^(D219) L_(C1173) R^(D168) R^(D219) L_(C850) R^(D17) R^(D220) L_(C958) R^(D50) R^(D220) L_(C1066) R^(D145) R^(D220) L_(C1174) R^(D168) R^(D220) L_(C851) R^(D17) R^(D221) L_(C959) R^(D50) R^(D221) L_(C1067) R^(D145) R^(D221) L_(C1175) R^(D168) R^(D221) L_(C852) R^(D17) R^(D222) L_(C960) R^(D50) R^(D222) L_(C1068) R^(D145) R^(D222) L_(C1176) R^(D168) R^(D222) L_(C853) R^(D17) R^(D223) L_(C961) R^(D50) R^(D223) L_(C1069) R^(D145) R^(D223) L_(C1177) R^(D168) R^(D223) L_(C854) R^(D17) R^(D224) L_(C962) R^(D50) R^(D224) L_(C1070) R^(D145) R^(D224) L_(C1178) R^(D168) R^(D224) L_(C855) R^(D17) R^(D225) L_(C963) R^(D50) R^(D225) L_(C1071) R^(D145) R^(D225) L_(C1179) R^(D168) R^(D225) L_(C856) R^(D17) R^(D226) L_(C964) R^(D50) R^(D226) L_(C1072) R^(D145) R^(D226) L_(C1180) R^(D168) R^(D226) L_(C857) R^(D17) R^(D227) L_(C965) R^(D50) R^(D227) L_(C1073) R^(D145) R^(D227) L_(C1181) R^(D168) R^(D227) L_(C858) R^(D17) R^(D228) L_(C966) R^(D50) R^(D228) L_(C1074) R^(D145) R^(D228) L_(C1182) R^(D168) R^(D228) L_(C859) R^(D17) R^(D229) L_(C967) R^(D50) R^(D229) L_(C1075) R^(D145) R^(D229) L_(C1183) R^(D168) R^(D229) L_(C860) R^(D17) R^(D230) L_(C968) R^(D50) R^(D230) L_(C1076) R^(D145) R^(D230) L_(C1184) R^(D168) R^(D230) L_(C861) R^(D17) R^(D231) L_(C969) R^(D50) R^(D231) L_(C1077) R^(D145) R^(D231) L_(C1185) R^(D168) R^(D231) L_(C862) R^(D17) R^(D232) L_(C970) R^(D50) R^(D232) L_(C1078) R^(D145) R^(D232) L_(C1186) R^(D168) R^(D232) L_(C863) R^(D17) R^(D233) L_(C971) R^(D50) R^(D233) L_(C1079) R^(D145) R^(D233) L_(C1187) R^(D168) R^(D233) L_(C864) R^(D17) R^(D234) L_(C972) R^(D50) R^(D234) L_(C1080) R^(D145) R^(D234) L_(C1188) R^(D168) R^(D234) L_(C865) R^(D17) R^(D235) L_(C973) R^(D50) R^(D235) L_(C1081) R^(D145) R^(D235) L_(C1189) R^(D168) R^(D235) L_(C866) R^(D17) R^(D236) L_(C974) R^(D50) R^(D236) L_(C1082) R^(D145) R^(D236) L_(C1190) R^(D168) R^(D236) L_(C867) R^(D17) R^(D237) L_(C975) R^(D50) R^(D237) L_(C1083) R^(D145) R^(D237) L_(C1191) R^(D168) R^(D237) L_(C868) R^(D17) R^(D238) L_(C976) R^(D50) R^(D238) L_(C1084) R^(D145) R^(D238) L_(C1192) R^(D168) R^(D238) L_(C869) R^(D17) R^(D239) L_(C977) R^(D50) R^(D239) L_(C1085) R^(D145) R^(D239) L_(C1193) R^(D168) R^(D239) L_(C870) R^(D17) R^(D240) L_(C978) R^(D50) R^(D240) L_(C1086) R^(D145) R^(D240) L_(C1194) R^(D168) R^(D240) L_(C871) R^(D17) R^(D241) L_(C979) R^(D50) R^(D241) L_(C1087) R^(D145) R^(D241) L_(C1195) R^(D168) R^(D241) L_(C872) R^(D17) R^(D242) L_(C980) R^(D50) R^(D242) L_(C1088) R^(D145) R^(D242) L_(C1196) R^(D168) R^(D242) L_(C873) R^(D17) R^(D243) L_(C981) R^(D50) R^(D243) L_(C1089) R^(D145) R^(D243) L_(C1197) R^(D168) R^(D243) L_(C874) R^(D17) R^(D244) L_(C982) R^(D50) R^(D244) L_(C1090) R^(D145) R^(D244) L_(C1198) R^(D168) R^(D244) L_(C875) R^(D17) R^(D245) L_(C983) R^(D50) R^(D245) L_(C1091) R^(D145) R^(D245) L_(C1199) R^(D168) R^(D245) L_(C876) R^(D17) R^(D246) L_(C984) R^(D50) R^(D246) L_(C1092) R^(D145) R^(D246) L_(C1200) R^(D168) R^(D246) L_(C1201) R^(D10) R^(D193) L_(C1255) R^(D55) R^(D193) L_(C1309) R^(D37) R^(D193) L_(C1363) R^(D143) R^(D193) L_(C1202) R^(D10) R^(D194) L_(C1256) R^(D55) R^(D194) L_(C1310) R^(D37) R^(D194) L_(C1364) R^(D143) R^(D194) L_(C1203) R^(D10) R^(D195) L_(C1257) R^(D55) R^(D195) L_(C1311) R^(D37) R^(D195) L_(C1365) R^(D143) R^(D195) L_(C1204) R^(D10) R^(D196) L_(C1258) R^(D55) R^(D196) L_(C1312) R^(D37) R^(D196) L_(C1366) R^(D143) R^(D196) L_(C1205) R^(D10) R^(D197) L_(C1259) R^(D55) R^(D197) L_(C1313) R^(D37) R^(D197) L_(C1367) R^(D143) R^(D197) L_(C1206) R^(D10) R^(D198) L_(C1260) R^(D55) R^(D198) L_(C1314) R^(D37) R^(D198) L_(C1368) R^(D143) R^(D198) L_(C1207) R^(D10) R^(D199) L_(C1261) R^(D55) R^(D199) L_(C1315) R^(D37) R^(D199) L_(C1369) R^(D143) R^(D199) L_(C1208) R^(D10) R^(D200) L_(C1262) R^(D55) R^(D200) L_(C1316) R^(D37) R^(D200) L_(C1370) R^(D143) R^(D200) L_(C1209) R^(D10) R^(D201) L_(C1263) R^(D55) R^(D201) L_(C1317) R^(D37) R^(D201) L_(C1371) R^(D143) R^(D201) L_(C1210) R^(D10) R^(D202) L_(C1264) R^(D55) R^(D202) L_(C1318) R^(D37) R^(D202) L_(C1372) R^(D143) R^(D202) L_(C1211) R^(D10) R^(D203) L_(C1265) R^(D55) R^(D203) L_(C1319) R^(D37) R^(D203) L_(C1373) R^(D143) R^(D203) L_(C1212) R^(D10) R^(D204) L_(C1266) R^(D55) R^(D204) L_(C1320) R^(D37) R^(D204) L_(C1374) R^(D143) R^(D204) L_(C1213) R^(D10) R^(D205) L_(C1267) R^(D55) R^(D205) L_(C1321) R^(D37) R^(D205) L_(C1375) R^(D143) R^(D205) L_(C1214) R^(D10) R^(D206) L_(C1268) R^(D55) R^(D206) L_(C1322) R^(D37) R^(D206) L_(C1376) R^(D143) R^(D206) L_(C1215) R^(D10) R^(D207) L_(C1269) R^(D55) R^(D207) L_(C1323) R^(D37) R^(D207) L_(C1377) R^(D143) R^(D207) L_(C1216) R^(D10) R^(D208) L_(C1270) R^(D55) R^(D208) L_(C1324) R^(D37) R^(D208) L_(C1378) R^(D143) R^(D208) L_(C1217) R^(D10) R^(D209) L_(C1271) R^(D55) R^(D209) L_(C1325) R^(D37) R^(D209) L_(C1379) R^(D143) R^(D209) L_(C1218) R^(D10) R^(D210) L_(C1272) R^(D55) R^(D210) L_(C1326) R^(D37) R^(D210) L_(C1380) R^(D143) R^(D210) L_(C1219) R^(D10) R^(D211) L_(C1273) R^(D55) R^(D211) L_(C1327) R^(D37) R^(D211) L_(C1381) R^(D143) R^(D211) L_(C1220) R^(D10) R^(D212) L_(C1274) R^(D55) R^(D212) L_(C1328) R^(D37) R^(D212) L_(C1382) R^(D143) R^(D212) L_(C1221) R^(D10) R^(D213) L_(C1275) R^(D55) R^(D213) L_(C1329) R^(D37) R^(D213) L_(C1383) R^(D143) R^(D213) L_(C1222) R^(D10) R^(D214) L_(C1276) R^(D55) R^(D214) L_(C1330) R^(D37) R^(D214) L_(C1384) R^(D143) R^(D214) L_(C1223) R^(D10) R^(D215) L_(C1277) R^(D55) R^(D215) L_(C1331) R^(D37) R^(D215) L_(C1385) R^(D143) R^(D215) L_(C1224) R^(D10) R^(D216) L_(C1278) R^(D55) R^(D216) L_(C1332) R^(D37) R^(D216) L_(C1386) R^(D143) R^(D216) L_(C1225) R^(D10) R^(D217) L_(C1279) R^(D55) R^(D217) L_(C1333) R^(D37) R^(D217) L_(C1387) R^(D143) R^(D217) L_(C1226) R^(D10) R^(D218) L_(C1280) R^(D55) R^(D218) L_(C1334) R^(D37) R^(D218) L_(C1388) R^(D143) R^(D218) L_(C1227) R^(D10) R^(D219) L_(C1281) R^(D55) R^(D219) L_(C1335) R^(D37) R^(D219) L_(C1389) R^(D143) R^(D219) L_(C1228) R^(D10) R^(D220) L_(C1282) R^(D55) R^(D220) L_(C1336) R^(D37) R^(D220) L_(C1390) R^(D143) R^(D220) L_(C1229) R^(D10) R^(D221) L_(C1283) R^(D55) R^(D221) L_(C1337) R^(D37) R^(D221) L_(C1391) R^(D143) R^(D221) L_(C1230) R^(D10) R^(D222) L_(C1284) R^(D55) R^(D222) L_(C1338) R^(D37) R^(D222) L_(C1392) R^(D143) R^(D222) L_(C1231) R^(D10) R^(D223) L_(C1285) R^(D55) R^(D223) L_(C1339) R^(D37) R^(D223) L_(C1393) R^(D143) R^(D223) L_(C1232) R^(D10) R^(D224) L_(C1286) R^(D55) R^(D224) L_(C1340) R^(D37) R^(D224) L_(C1394) R^(D143) R^(D224) L_(C1233) R^(D10) R^(D225) L_(C1287) R^(D55) R^(D225) L_(C1341) R^(D37) R^(D225) L_(C1395) R^(D143) R^(D225) L_(C1234) R^(D10) R^(D226) L_(C1288) R^(D55) R^(D226) L_(C1342) R^(D37) R^(D226) L_(C1396) R^(D143) R^(D226) L_(C1235) R^(D10) R^(D227) L_(C1289) R^(D55) R^(D227) L_(C1343) R^(D37) R^(D227) L_(C1397) R^(D143) R^(D227) L_(C1236) R^(D10) R^(D228) L_(C1290) R^(D55) R^(D228) L_(C1344) R^(D37) R^(D228) L_(C1398) R^(D143) R^(D228) L_(C1237) R^(D10) R^(D229) L_(C1291) R^(D55) R^(D229) L_(C1345) R^(D37) R^(D229) L_(C1399) R^(D143) R^(D229) L_(C1238) R^(D10) R^(D230) L_(C1292) R^(D55) R^(D230) L_(C1346) R^(D37) R^(D230) L_(C1400) R^(D143) R^(D230) L_(C1239) R^(D10) R^(D231) L_(C1293) R^(D55) R^(D231) L_(C1347) R^(D37) R^(D231) L_(C1401) R^(D143) R^(D231) L_(C1240) R^(D10) R^(D232) L_(C1294) R^(D55) R^(D232) L_(C1348) R^(D37) R^(D232) L_(C1402) R^(D143) R^(D232) L_(C1241) R^(D10) R^(D233) L_(C1295) R^(D55) R^(D233) L_(C1349) R^(D37) R^(D233) L_(C1403) R^(D143) R^(D233) L_(C1242) R^(D10) R^(D234) L_(C1296) R^(D55) R^(D234) L_(C1350) R^(D37) R^(D234) L_(C1404) R^(D143) R^(D234) L_(C1243) R^(D10) R^(D235) L_(C1297) R^(D55) R^(D235) L_(C1351) R^(D37) R^(D235) L_(C1405) R^(D143) R^(D235) L_(C1244) R^(D10) R^(D236) L_(C1298) R^(D55) R^(D236) L_(C1352) R^(D37) R^(D236) L_(C1406) R^(D143) R^(D236) L_(C1245) R^(D10) R^(D237) L_(C1299) R^(D55) R^(D237) L_(C1353) R^(D37) R^(D237) L_(C1407) R^(D143) R^(D237) L_(C1246) R^(D10) R^(D238) L_(C1300) R^(D55) R^(D238) L_(C1354) R^(D37) R^(D238) L_(C1408) R^(D143) R^(D238) L_(C1247) R^(D10) R^(D239) L_(C1301) R^(D55) R^(D239) L_(C1355) R^(D37) R^(D239) L_(C1409) R^(D143) R^(D239) L_(C1248) R^(D10) R^(D240) L_(C1302) R^(D55) R^(D240) L_(C1356) R^(D37) R^(D240) L_(C1410) R^(D143) R^(D240) L_(C1249) R^(D10) R^(D241) L_(C1303) R^(D55) R^(D241) L_(C1357) R^(D37) R^(D241) L_(C1411) R^(D143) R^(D241) L_(C1250) R^(D10) R^(D242) L_(C1304) R^(D55) R^(D242) L_(C1358) R^(D37) R^(D242) L_(C1412) R^(D143) R^(D242) L_(C1251) R^(D10) R^(D243) L_(C1305) R^(D55) R^(D243) L_(C1359) R^(D37) R^(D243) L_(C1413) R^(D143) R^(D243) L_(C1252) R^(D10) R^(D244) L_(C1306) R^(D55) R^(D244) L_(C1360) R^(D37) R^(D244) L_(C1414) R^(D143) R^(D244) L_(C1253) R^(D10) R^(D245) L_(C1307) R^(D55) R^(D245) L_(C1361) R^(D37) R^(D245) L_(C1415) R^(D143) R^(D245) L_(C1254) R^(D10) R^(D246) L_(C1308) R^(D55) R^(D246) L_(C1362) R^(D37) R^(D246) L_(C1416) R^(D143) R^(D246) wherein R^(D1) to R^(D246) have the following structures:

In some embodiments, the compound has the formula Ir(L_(Ai-m))(L_(Bk))₂, Ir(L_(Ai-m′))(L_(Bk))₂, or Ir(L_(Ai′-m″))₂(L_(Bk)), wherein the compound is selected from the group consisting of only those compounds whose L_(Bk) ligand corresponds to one of the structures in the following LIST 7:

L_(B1), L_(B2), L_(B18), L_(B28), L_(B38), L_(B108), L_(B118), L_(B122), L_(B124), L_(B126), L_(B128), L_(B130), L_(B132), L_(B134), L_(B136), L_(B138), L_(B140), L_(B142), L_(B144), L_(B156), L_(B158), L_(B160), L_(B162), L_(B164), L_(B168), L_(B172), L_(B175), L_(B204), L_(B206), L_(B214), L_(B216), L_(B218), L_(B220), L_(B222), L_(B231), L_(B233), L_(B235), L_(B237), L_(B240), L_(B242), L_(B244), L_(B246), L_(B248), L_(B250), L_(B252), L_(B254), L_(B256), L_(B258), L_(B260), L_(B262) and L_(B264), L_(B265), L_(B266), L_(B267), L_(B268), L_(B269), and L_(B270).

In some embodiments, the compound has the formula Ir(L_(Ai-m))(L_(Bk))₂, Ir(L_(Ai-m′))(L_(Bk))₂, or Ir(L_(Ai′-m″))₂(L_(Bk)), wherein the compound is selected from the group consisting of only those compounds whose L_(Bk) ligand corresponds to one of the following structures:

L_(B1), L_(B2), L_(B18), L_(B28), L_(B38), L_(B108), L_(B118), L_(B122), L_(B126), L_(B128), L_(B132), L_(B136), L_(B138), L_(B142), L_(B156), L_(B162), L_(B204), L_(B206), L_(B214), L_(B216), L_(B218), L_(B220), L_(B231), L_(B233), L_(B237), L_(B264), L_(B265), L_(B266), L_(B267), L_(B268), L_(B269), and L_(B270).

In some embodiments, the compound has the formula Ir(L_(Ai-m))₂(L_(Cj-I)), Ir(L_(Ai-m′))₂(L_(Cj-I)), Ir(L_(Ai′-m″))₂(L_(Cj-I)), Ir(L_(Ai-m))₂(L_(Cj-I)), Ir(L_(Ai-m′))₂(L_(Cj-I)), or Ir(L_(Ai′-m″))₂(L_(Cj-II)), wherein the compound is selected from the group consisting of only those compounds having ligands L_(Cj-I) or L_(Cj-II), whose corresponding R²⁰¹ and R²⁰² are defined to be one of the structures in the following LIST 8:

R^(D1), R^(D3), R^(D4), R^(D5), R^(D9), R^(D10), R^(D17), R^(D18), R^(D20), R^(D22), R^(D37), R^(D40), R^(D41), R^(D42), R^(D43), R^(D48), R^(D49), R^(D50), R^(D54), R^(D55), R^(D58), R^(D59), R^(D78), R^(D79), R^(D81), R^(D87), R^(D88), R^(D89), R^(D93), R^(D116), R^(D117), R^(D118), R^(D119), R^(D120), R^(D133), R^(D134), R^(D135), R^(D136), R^(D143), R^(D144), R^(D145), R^(D146), R^(D147), R^(D149), R^(D151), R^(D154), R^(D155), R^(D161), R^(D175), R^(D190), R^(D193), R^(D200), R^(D201), R^(D206), R^(D210), R^(D214), R^(D215), R^(D216), R^(D218), R^(D219), R^(D220), R^(D227), R^(D237), R^(D241), R^(D242), R^(D245), and R^(D246).

In some embodiments, the compound has the formula Ir(L_(Ai-m))₂(L_(Cj-I)), Ir(L_(Ai-m′))₂(L_(Cj-I)), Ir(L_(Ai′-m″))₂(L_(Cj-I)), Ir(L_(Ai-m))₂(L_(Cj-I)), Ir(L_(Ai-m′))₂(L_(Cj-I)), or Ir(L_(Ai′-m″))₂(L_(Cj-II)), wherein the compound is selected from the group consisting of only those compounds having ligands L_(Cj-I) or L_(Cj-II), whose corresponding R²⁰¹ and R²⁰² are defined to be one the following structures:

R^(D1), R^(D3), R^(D4), R^(D5), R^(D9), R^(D10), R^(D17), R^(D22), R^(D43), R^(D50), R^(D78), R^(D116), R^(D118), R^(D133), R^(D134), R^(D135), R^(D136), R^(D143), R^(D144), R^(D145), R^(D146), R^(D149), R^(D151), R^(D154), R^(D155), R^(D190), R^(D193), R^(D200), R^(D201), R^(D206), R^(D210), R^(D214), R^(D215), R^(D216), R^(D218), R^(D219), R^(D220), R^(D227), R^(D237), R^(D241), R^(D242), R^(D245), and R^(D246).

In some embodiments, the compound has the formula Ir(L_(Ai-m))₂(L_(Cj-I)), Ir(L_(Ai-m′))₂(L_(Cj-I)), or Ir(L_(Ai′-m″))₂(L_(Cj-I)), and the compound is selected from the group consisting of only those compounds having one of the structures shown below in LIST 9 for the L_(Cj-I) ligand:

In some embodiments, the compound can be selected from the group consisting of the structures shown below in LIST 10:

In some embodiments, the compound can have a structure of

wherein:

M¹ is Pd or Pt;

each of moieties E and F is independently monocyclic or polycyclic ring structure comprising 5-membered and/or 6-membered carbocyclic or heterocyclic rings; Z³ and Z⁴ are each independently C or N; K¹, K², K³, and K⁴ are each independently selected from the group consisting of a direct bond, O, and S, wherein at least two of K¹, K², K³, and K⁴ are direct bonds; L¹, L², and L³ are each independently selected from the group consisting of a single bond, absent a bond, O, S, SO, SO₂, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, and NR, wherein at least one of L¹ and L² is present; X⁵-X⁷ are each independently C or N; R^(E) and R^(F) each independently represents zero, mono, or up to the maximum allowed number of substitutions to its associated ring; each of R^(E), and R^(F) is independently a hydrogen or a substituent selected from the group consisting of deuterium, fluorine, alkyl, cycloalkyl, heteroalkyl, alkoxy, aryloxy, amino, silyl, boryl, alkenyl, cycloalkenyl, heteroalkenyl, aryl, heteroaryl, nitrile, isonitrile, sulfanyl, and combinations thereof; two adjacent R, R′, R^(A), R^(B), R^(C), R^(D), R^(E), or R^(F) can be joined or fused together to form a ring where chemically feasible; and the remaining variables are all the same as previously defined.

In some embodiments, moiety E and moiety F can be both 6-membered aromatic rings. In some embodiments, moiety F can be a 5-membered or 6-membered heteroaromatic ring.

In some embodiments, Z³ can be N and Z⁴ can be C. In some embodiments, Z³ can be C and Z⁴ can be N.

In some embodiments, L¹ can be O or CRR′. In some embodiments, L² can be a direct bond. In some embodiments, L² can be NR.

In some embodiments, K¹, K², K³, and K⁴ can be all direct bonds. In some embodiments, one of K¹, K², K³, or K⁴ can be O. In some embodiments, one of K¹, or K² can be O.

In some embodiments, X⁵-X⁷ can be all C.

In some embodiments, the compound can be selected from the group consisting of the structures shown below in LIST 11:

wherein: R^(x) and R^(y) are each selected from the group consisting of alkyl, cycloalkyl, heteroalkyl, heterocycloalkyl, aryl, heteroaryl, and combinations thereof, R^(G) for each occurrence is independently a hydrogen or a substituent selected from the group consisting of deuterium, fluorine, alkyl, cycloalkyl, heteroalkyl, alkoxy, aryloxy, amino, silyl, boryl, alkenyl, cycloalkenyl, heteroalkenyl, aryl, heteroaryl, nitrile, isonitrile, sulfanyl, and combinations thereof; and the remaining variables are all the same as previously defined.

In some embodiments, the compound can be selected from the group consisting of formula Pt(L_(A′))L_(y), wherein L_(A′) is selected from the structures in the following LIST 12, wherein s is an integer from 1 to 50, t is an integer from 1 to 6, and u is an integer from 1 to 4:

L_(A’) Structure of L_(A’) L_(A’)1-(s)(t)(u), wherein L_(A’)- (1)(1)(1) to L_(A’)1- (50)(6)(4), having the structure

L_(A’)2-(s)(t)(u), wherein L_(A’)2- (1)(1)(1) to L_(A’)2- (50)(6)(4), having the structure

L_(A’)3-(s)(t)(u), wherein L_(A’)3- (1)(1)(1) to L_(A’)3- (50)(6)(4), having the structure

L_(A’)4-(s)(t)(u), wherein L_(A’)4- (1)(1)(1) to L_(A’)4- (50)(6)(4), having the structure

L_(A’)5-(s)(t)(u), wherein L_(A’)5- (1)(1)(1) to L_(A’)5- (50)(6)(4), having the structure

L_(A’)6-(s)(t)(u), wherein L_(A’)6- (1)(1)(1) to L_(A’)6- (50)(6)(4), having the structure

L_(A’)7-(s)(t)(u), wherein L_(A’)7- (1)(1)(1) to L_(A’)7- (50)(6)(4), having the structure

L_(A’)8-(s)(t)(u), wherein L_(A’)8- (1)(1)(1) to L_(A’)8- (50)(6)(4), having the structure

L_(A’)9-(s)(t)(u), wherein L_(A’)9- (1)(1)(1) to L_(A’)9- (50)(6)(4), having the structure

L_(A’)10-(s)(t)(u), wherein L_(A’)10- (1)(1)(1) to L_(A’)10- (50)(6)(4), having the structure

L_(A’)11-(s)(t)(u), wherein L_(A’)11- (1)(1)(1) to L_(A’)11- (50)(6)(4), having the structure

L_(A’)12-(s)(t)(u), wherein L_(A’)12- (1)(1)(1) to L_(A’)12- (50)(6)(4), having the structure

L_(A’)13-(s)(t)(u), wherein L_(A’)13- (1)(1)(1) to L_(A’)13- (50)(6)(4), having the structure

L_(A’)14-(s)(t)(u), wherein L_(A’)14- (1)(1)(1) to L_(A’)14- (50)(6)(4), having the structure

L_(A’)15-(s)(t)(u), wherein L_(A’)15- (1)(1)(1) to L_(A’)15- (50)(3)(4), having the structure

L_(A’)16-(s)(t)(u), wherein L_(A’)16- (1)(1)(1) to L_(A’)16- (50)(3)(4), having the structure

L_(A’)17-(s)(t)(u), wherein L_(A’)17- (1)(1)(1) to L _(A’)17- (50)(3)(4), having the structure

L_(A’)18-(s)(t)(u), wherein L_(A’)18- (1)(1)(1) to L_(A’)18- (50)(3)(4), having the structure

L_(A’)19-(s)(t)(u), wherein L_(A’)19- (1)(1)(1) to L_(A’)19- (50)(3)(4), having the structure

L_(A’)20-(s)(u), wherein L_(A’)20- (1)(1) to L_(A’)20- (50)(4), having the structure

L_(A’)21-(s)(u), wherein L_(A’)21- (1)(1) to L_(A’)21- (50)(4), having the structure

L_(A’)22-(s)(u), wherein L_(A’)22- (1)(1) to L_(A’)22- (50)(4), having the structure

wherein L_(y) is selected from the group consisting of the structures shown below in LIST 13, wherein o, p, and q are each independently an integer from 1 to 50, and t is an integer from 1 to 6:

L_(y) Structure of L_(y) L_(y)1-(o)(p)(q), wherein L_(y)1-(1)(1)(1) to L_(y)l- (50)(50)(50), having the structure

L_(y)2-(o)(p)(q), wherein L_(y)2-(1)(1)(1) to L_(y)2-- (50)(50)(50), having the structure

L_(y)3-(o)(p)(q), wherein L_(y)3-(1)(1)(1) to L_(y)3-- (50)(50)(50), having the structure

L_(y)4-(o)(p)(q), wherein L_(y)4-(1)(1)(1) to L_(y)4-- (50)(50)(50), having the structure

L_(y)5-(o)(p)(q), wherein L_(y)5-(1)(1)(1) to L_(y)5-- (50)(50)(50), having the structure

L_(y)6-(o)(t), wherein L_(y)6- (1)(1) to L_(y)6-(50)(6), having the structure

L_(y)7-(o)(t), wherein L_(y)7- (1)(1) to L_(y)7-(50)(6), having the structure

L_(y)8-(o)(t), wherein L_(y)8- (1)(1) to L_(y)8-(50)(6), having the structure

L_(y)9-(o)(t), wherein L_(y)9- (1)(1) to L_(y)9-(50)(6), having the structure

L_(y)10-(o)(t), wherein L_(y)10-(1)(1) to L_(y)10- (50)(6), having the structure

L_(y)11-(o)(t), wherein L_(y)11-(1)(1) to L_(y)11- (50)(6), having the structure

L_(y)12-(o)(t), wherein L_(y)12-(1)(1) to L_(y)12- (50)(6), having the structure

L_(y)13-(o)(t), wherein L_(y)13-(1)(1) to L_(y)13- (50)(6), having the structure

L_(y)14-(o)(t), wherein L_(y)14-(1)(1) to L_(y)14- (50)(6), having the structure

L_(y)15-(o)(t), wherein L_(y)15-(1)(1) to L_(y)15- (50)(6), having the structure

L_(y)16-(o)(t), wherein L_(y)16-(1)(1) to L_(y)16- (50)(6), having the structure

L_(y)17-(o)(t), wherein L_(y)17-(1)(1) to L_(y)17- (50)(6), having the structure

L_(y)18-(o)(t), wherein L_(y)18-(1)(1) to L_(y)18- (50)(6), having the structure

L_(y)19-(o)(t), wherein L_(y)19-(1)(1) to L_(y)19- (50)(6), having the structure

L_(y)2-(o)(t), wherein L_(y)2-(1)(1) to L_(y)2- (50)(6), having the structure

L_(y)21-(o)(t), wherein L_(y)21-(1)(1) to L_(y)21- (50)(6), having the structure

L_(y)22-(o)(t), wherein L_(y)22-(1)(1) to L_(y)22- (50)(6), having the structure

L_(y)23-(o)(t), wherein L_(y)23-(1)(1) to L_(y)23- (50)(6), having the structure

L_(y)24-(o)(t), wherein L_(y)24-(1)(1) to L_(y)24- (50)(6), having the structure

L_(y)25-(o), wherein L_(y)25- (1) to L_(y)25-(50), having the structure

L_(y)26-(o), wherein L_(y)26- (1) to L_(y)26-(50), having the structure

L_(y)27-(o), wherein L_(y)27- (1) to L_(y)27-(50), having the structure

wherein R1 to R50 have the following structures:

wherein T1 to T6 have the following structures:

wherein each Q1 to Q4 have the following structures: direct bond O S NPh Q1, Q2, Q3, and Q4.

In some embodiments, the compound having a ligand L_(A) of Formula I described herein can be at least 30% deuterated, at least 40% deuterated, at least 50% deuterated, at least 60% deuterated, at least 70% deuterated, at least 80% deuterated, at least 90% deuterated, at least 95% deuterated, at least 99% deuterated, or 100% deuterated. As used herein, percent deuteration has its ordinary meaning and includes the percent of possible hydrogen atoms (e.g., positions that are hydrogen or deuterium) that are replaced by deuterium atoms.

C. The OLEDs and the Devices of the Present Disclosure

In another aspect, the present disclosure also provides an OLED device comprising an organic layer that contains a compound as disclosed in the above compounds section of the present disclosure.

In some embodiments, the organic layer may comprise a compound comprising a ligand L_(A) having a structure of

wherein one of Z¹ and Z² is C and the other is N; each of K¹ or K² is independently a direct bond, O, or S; moiety B, moiety C, and moiety D are each independently monocyclic or polycyclic ring structure containing 5-membered or 6-membered carbocyclic or heterocyclic rings; X¹-X⁴ are each independently C or N, with at least one of X¹ or X² being N if both moiety B and moiety C of Formula I are monocyclic 6-membered aromatic rings; the maximum number of N atoms that can connect to each other within a ring is two; Y is selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; W is selected from the group consisting of O, S, S═O, SO₂, NR, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, GeRR′, PR, P═O, and P═S; each of R^(A), R^(B), R^(C), and R^(D) independently represents zero, mono, or up to the maximum allowed number of substitutions to its associated ring; each of R, R′, R^(A), R^(B), R^(C), and R^(D) is independently a hydrogen or a substituent selected from the group consisting of the general substituents defined herein; and any two adjacent R, R′, R^(A), R^(B), R^(C), or R^(D) can be joined or fused together to form a ring, wherein the ligand L_(A) is coordinated to a metal M by the two indicated dashed lines; wherein M is selected from the group consisting of Ru, Os, Ir, Pd, Pt, Cu, Ag, and Au; and wherein the ligand L_(A) can be joined with other ligands to form a tridentate, tetradentate, pentadentate, or hexadentate ligand. In some embodiments, the organic layer may be an emissive layer and the compound as described herein may be an emissive dopant or a non-emissive dopant.

In some embodiments, the organic layer may further comprise a host, wherein the host comprises a triphenylene containing benzo-fused thiophene or benzo-fused furan, wherein any substituent in the host is an unfused substituent independently selected from the group consisting of C_(n)H_(2n+1), OC_(n)H_(2n+1), OAr₁, N(C_(n)H_(2n+1))₂, N(Ar₁)(Ar₂), CH═CH—C_(n)H_(2n+1), C≡CC_(n)H_(2n+1), Ar₁, Ar₁-Ar₂, C_(n)H_(2n)—Ar₁, or no substitution, wherein n is from 1 to 10; and wherein Ar₁ and Ar₂ are independently selected from the group consisting of benzene, biphenyl, naphthalene, triphenylene, carbazole, and heteroaromatic analogs thereof.

In some embodiments, the organic layer may further comprise a host, wherein host comprises at least one chemical moiety selected from the group consisting of naphthalene, fluorene, triphenylene, carbazole, indolocarbazole, dibenzothiophene, dibenzofuran, dibenzoselenophene, 5,9-dioxa-13b-boranaphtho[3,2,1-de]anthracene, aza-naphthalene, aza-fluorene, aza-triphenylene, aza-carbazole, aza-indolocarbazole, aza-dibenzothiophene, aza-dibenzofuran, aza-dibenzoselenophene, and aza-(5,9-dioxa-13b-boranaphtho[3,2,1-de]anthracene).

In some embodiments, the host may be selected from the group consisting of:

and combinations thereof.

In some embodiments, the organic layer may further comprise a host, wherein the host comprises a metal complex.

In some embodiments, the compound as described herein may be a sensitizer; wherein the device may further comprise an acceptor; and wherein the acceptor may be selected from the group consisting of fluorescent emitter, delayed fluorescence emitter, and combination thereof.

In yet another aspect, the OLED of the present disclosure may also comprise an emissive region containing a compound as disclosed in the above compounds section of the present disclosure.

In some embodiments, the emissive region may comprise a compound comprising a ligand L_(A) having a structure of

wherein one of Z¹ and Z² is C and the other is N; each of K¹ or K² is independently a direct bond, O, or S; moiety B, moiety C, and moiety D are each independently monocyclic or polycyclic ring structure containing 5-membered or 6-membered carbocyclic or heterocyclic rings; X¹-X⁴ are each independently C or N, with at least one of X¹ or X² being N if both moiety B and moiety C of Formula I are monocyclic 6-membered aromatic rings; the maximum number of N atoms that can connect to each other within a ring is two; Y is selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; W is selected from the group consisting of O, S, S═O, SO₂, NR, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, GeRR′, PR, P═O, and P═S; each of R^(A), R^(B), R^(C), and R^(D) independently represents zero, mono, or up to the maximum allowed number of substitutions to its associated ring; each of R, R′, R^(A), R^(B), R_(C), and R^(D) is independently a hydrogen or a substituent selected from the group consisting of the general substituents defined herein; and any two adjacent R, R′, R^(A), R^(B), R^(C), or R^(D) can be joined or fused together to form a ring, wherein the ligand L_(A) is coordinated to a metal M by the two indicated dashed lines; wherein M is selected from the group consisting of Ru, Os, Ir, Pd, Pt, Cu, Ag, and Au; and wherein the ligand L_(A) can be joined with other ligands to form a tridentate, tetradentate, pentadentate, or hexadentate ligand.

In some embodiments, at least one of the anode, the cathode, or a new layer disposed over the organic emissive layer functions as an enhancement layer. The enhancement layer comprises a plasmonic material exhibiting surface plasmon resonance that non-radiatively couples to the emitter material and transfers excited state energy from the emitter material to non-radiative mode of surface plasmon polariton. The enhancement layer is provided no more than a threshold distance away from the organic emissive layer, wherein the emitter material has a total non-radiative decay rate constant and a total radiative decay rate constant due to the presence of the enhancement layer and the threshold distance is where the total non-radiative decay rate constant is equal to the total radiative decay rate constant. In some embodiments, the OLED further comprises an outcoupling layer. In some embodiments, the outcoupling layer is disposed over the enhancement layer on the opposite side of the organic emissive layer. In some embodiments, the outcoupling layer is disposed on opposite side of the emissive layer from the enhancement layer but still outcouples energy from the surface plasmon mode of the enhancement layer. The outcoupling layer scatters the energy from the surface plasmon polaritons. In some embodiments this energy is scattered as photons to free space. In other embodiments, the energy is scattered from the surface plasmon mode into other modes of the device such as but not limited to the organic waveguide mode, the substrate mode, or another waveguiding mode. If energy is scattered to the non-free space mode of the OLED other outcoupling schemes could be incorporated to extract that energy to free space. In some embodiments, one or more intervening layer can be disposed between the enhancement layer and the outcoupling layer. The examples for interventing layer(s) can be dielectric materials, including organic, inorganic, perovskites, oxides, and may include stacks and/or mixtures of these materials.

The enhancement layer modifies the effective properties of the medium in which the emitter material resides resulting in any or all of the following: a decreased rate of emission, a modification of emission line-shape, a change in emission intensity with angle, a change in the stability of the emitter material, a change in the efficiency of the OLED, and reduced efficiency roll-off of the OLED device. Placement of the enhancement layer on the cathode side, anode side, or on both sides results in OLED devices which take advantage of any of the above-mentioned effects. In addition to the specific functional layers mentioned herein and illustrated in the various OLED examples shown in the figures, the OLEDs according to the present disclosure may include any of the other functional layers often found in OLEDs.

The enhancement layer can be comprised of plasmonic materials, optically active metamaterials, or hyperbolic metamaterials. As used herein, a plasmonic material is a material in which the real part of the dielectric constant crosses zero in the visible or ultraviolet region of the electromagnetic spectrum. In some embodiments, the plasmonic material includes at least one metal. In such embodiments the metal may include at least one of Ag, Al, Au, Ir, Pt, Ni, Cu, W, Ta, Fe, Cr, Mg, Ga, Rh, Ti, Ru, Pd, In, Bi, Ca alloys or mixtures of these materials, and stacks of these materials. In general, a metamaterial is a medium composed of different materials where the medium as a whole acts differently than the sum of its material parts. In particular, we define optically active metamaterials as materials which have both negative permittivity and negative permeability. Hyperbolic metamaterials, on the other hand, are anisotropic media in which the permittivity or permeability are of different sign for different spatial directions. Optically active metamaterials and hyperbolic metamaterials are strictly distinguished from many other photonic structures such as Distributed Bragg Reflectors (“DBRs”) in that the medium should appear uniform in the direction of propagation on the length scale of the wavelength of light. Using terminology that one skilled in the art can understand: the dielectric constant of the metamaterials in the direction of propagation can be described with the effective medium approximation. Plasmonic materials and metamaterials provide methods for controlling the propagation of light that can enhance OLED performance in a number of ways.

In some embodiments, the enhancement layer is provided as a planar layer. In other embodiments, the enhancement layer has wavelength-sized features that are arranged periodically, quasi-periodically, or randomly, or sub-wavelength-sized features that are arranged periodically, quasi-periodically, or randomly. In some embodiments, the wavelength-sized features and the sub-wavelength-sized features have sharp edges.

In some embodiments, the outcoupling layer has wavelength-sized features that are arranged periodically, quasi-periodically, or randomly, or sub-wavelength-sized features that are arranged periodically, quasi-periodically, or randomly. In some embodiments, the outcoupling layer may be composed of a plurality of nanoparticles and in other embodiments the outcoupling layer is composed of a plurality of nanoparticles disposed over a material. In these embodiments the outcoupling may be tunable by at least one of varying a size of the plurality of nanoparticles, varying a shape of the plurality of nanoparticles, changing a material of the plurality of nanoparticles, adjusting a thickness of the material, changing the refractive index of the material or an additional layer disposed on the plurality of nanoparticles, varying a thickness of the enhancement layer, and/or varying the material of the enhancement layer. The plurality of nanoparticles of the device may be formed from at least one of metal, dielectric material, semiconductor materials, an alloy of metal, a mixture of dielectric materials, a stack or layering of one or more materials, and/or a core of one type of material and that is coated with a shell of a different type of material. In some embodiments, the outcoupling layer is composed of at least metal nanoparticles wherein the metal is selected from the group consisting of Ag, Al, Au, Ir, Pt, Ni, Cu, W, Ta, Fe, Cr, Mg, Ga, Rh, Ti, Ru, Pd, In, Bi, Ca, alloys or mixtures of these materials, and stacks of these materials. The plurality of nanoparticles may have additional layer disposed over them. In some embodiments, the polarization of the emission can be tuned using the outcoupling layer. Varying the dimensionality and periodicity of the outcoupling layer can select a type of polarization that is preferentially outcoupled to air. In some embodiments the outcoupling layer also acts as an electrode of the device.

In yet another aspect, the present disclosure also provides a consumer product comprising an organic light-emitting device (OLED) having an anode; a cathode; and an organic layer disposed between the anode and the cathode, wherein the organic layer may comprise a compound as disclosed in the above compounds section of the present disclosure.

In some embodiments, the consumer product comprises an organic light-emitting device (OLED) having an anode; a cathode; and an organic layer disposed between the anode and the cathode, wherein the organic layer may comprise a compound comprising a ligand L_(A) having a structure of

wherein one of Z¹ and Z² is C and the other is N; each of K¹ or K² is independently a direct bond, O, or S; moiety B, moiety C, and moiety D are each independently monocyclic or polycyclic ring structure containing 5-membered or 6-membered carbocyclic or heterocyclic rings; X¹-X⁴ are each independently C or N, with at least one of X¹ or X² being N if both moiety B and moiety C of Formula I are monocyclic 6-membered aromatic rings; the maximum number of N atoms that can connect to each other within a ring is two; Y is selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; W is selected from the group consisting of O, S, S═O, SO₂, NR, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, GeRR′, PR, P═O, and P═S; each of R^(A), R^(B), R^(C), and R^(D) independently represents zero, mono, or up to the maximum allowed number of substitutions to its associated ring; each of R, R′, R^(A), R^(B), R^(C), and R^(D) is independently a hydrogen or a substituent selected from the group consisting of the general substituents defined herein; and any two adjacent R, R′, R^(A), R^(B), R^(C), or R^(D) can be joined or fused together to form a ring, wherein the ligand L_(A) is coordinated to a metal M by the two indicated dashed lines; wherein M is selected from the group consisting of Ru, Os, Ir, Pd, Pt, Cu, Ag, and Au; and wherein the ligand L_(A) can be joined with other ligands to form a tridentate, tetradentate, pentadentate, or hexadentate ligand.

In some embodiments, the consumer product can be one of a flat panel display, a computer monitor, a medical monitor, a television, a billboard, a light for interior or exterior illumination and/or signaling, a heads-up display, a fully or partially transparent display, a flexible display, a laser printer, a telephone, a cell phone, tablet, a phablet, a personal digital assistant (PDA), a wearable device, a laptop computer, a digital camera, a camcorder, a viewfinder, a micro-display that is less than 2 inches diagonal, a 3-D display, a virtual reality or augmented reality display, a vehicle, a video wall comprising multiple displays tiled together, a theater or stadium screen, a light therapy device, and a sign.

Generally, an OLED comprises at least one organic layer disposed between and electrically connected to an anode and a cathode. When a current is applied, the anode injects holes and the cathode injects electrons into the organic layer(s). The injected holes and electrons each migrate toward the oppositely charged electrode. When an electron and hole localize on the same molecule, an “exciton,” which is a localized electron-hole pair having an excited energy state, is formed. Light is emitted when the exciton relaxes via a photoemissive mechanism. In some cases, the exciton may be localized on an excimer or an exciplex. Non-radiative mechanisms, such as thermal relaxation, may also occur, but are generally considered undesirable.

Several OLED materials and configurations are described in U.S. Pat. Nos. 5,844,363, 6,303,238, and 5,707,745, which are incorporated herein by reference in their entirety.

The initial OLEDs used emissive molecules that emitted light from their singlet states (“fluorescence”) as disclosed, for example, in U.S. Pat. No. 4,769,292, which is incorporated by reference in its entirety. Fluorescent emission generally occurs in a time frame of less than 10 nanoseconds.

More recently, OLEDs having emissive materials that emit light from triplet states (“phosphorescence”) have been demonstrated. Baldo et al., “Highly Efficient Phosphorescent Emission from Organic Electroluminescent Devices,” Nature, vol. 395, 151-154, 1998; (“Baldo-I”) and Baldo et al., “Very high-efficiency green organic light-emitting devices based on electrophosphorescence,” Appl. Phys. Lett., vol. 75, No. 3, 4-6 (1999) (“Baldo-II”), are incorporated by reference in their entireties. Phosphorescence is described in more detail in U.S. Pat. No. 7,279,704 at cols. 5-6, which are incorporated by reference.

FIG. 1 shows an organic light emitting device 100. The figures are not necessarily drawn to scale. Device 100 may include a substrate 110, an anode 115, a hole injection layer 120, a hole transport layer 125, an electron blocking layer 130, an emissive layer 135, a hole blocking layer 140, an electron transport layer 145, an electron injection layer 150, a protective layer 155, a cathode 160, and a barrier layer 170. Cathode 160 is a compound cathode having a first conductive layer 162 and a second conductive layer 164. Device 100 may be fabricated by depositing the layers described, in order. The properties and functions of these various layers, as well as example materials, are described in more detail in U.S. Pat. No. 7,279,704 at cols. 6-10, which are incorporated by reference.

More examples for each of these layers are available. For example, a flexible and transparent substrate-anode combination is disclosed in U.S. Pat. No. 5,844,363, which is incorporated by reference in its entirety. An example of a p-doped hole transport layer is m-MTDATA doped with F₄-TCNQ at a molar ratio of 50:1, as disclosed in U.S. Patent Application Publication No. 2003/0230980, which is incorporated by reference in its entirety. Examples of emissive and host materials are disclosed in U.S. Pat. No. 6,303,238 to Thompson et al., which is incorporated by reference in its entirety. An example of an n-doped electron transport layer is BPhen doped with Li at a molar ratio of 1:1, as disclosed in U.S. Patent Application Publication No. 2003/0230980, which is incorporated by reference in its entirety. U.S. Pat. Nos. 5,703,436 and 5,707,745, which are incorporated by reference in their entireties, disclose examples of cathodes including compound cathodes having a thin layer of metal such as Mg:Ag with an overlying transparent, electrically-conductive, sputter-deposited ITO layer. The theory and use of blocking layers is described in more detail in U.S. Pat. No. 6,097,147 and U.S. Patent Application Publication No. 2003/0230980, which are incorporated by reference in their entireties. Examples of injection layers are provided in U.S. Patent Application Publication No. 2004/0174116, which is incorporated by reference in its entirety. A description of protective layers may be found in U.S. Patent Application Publication No. 2004/0174116, which is incorporated by reference in its entirety.

FIG. 2 shows an inverted OLED 200. The device includes a substrate 210, a cathode 215, an emissive layer 220, a hole transport layer 225, and an anode 230. Device 200 may be fabricated by depositing the layers described, in order. Because the most common OLED configuration has a cathode disposed over the anode, and device 200 has cathode 215 disposed under anode 230, device 200 may be referred to as an “inverted” OLED. Materials similar to those described with respect to device 100 may be used in the corresponding layers of device 200. FIG. 2 provides one example of how some layers may be omitted from the structure of device 100.

The simple layered structure illustrated in FIGS. 1 and 2 is provided by way of non-limiting example, and it is understood that embodiments of the present disclosure may be used in connection with a wide variety of other structures. The specific materials and structures described are exemplary in nature, and other materials and structures may be used. Functional OLEDs may be achieved by combining the various layers described in different ways, or layers may be omitted entirely, based on design, performance, and cost factors. Other layers not specifically described may also be included. Materials other than those specifically described may be used. Although many of the examples provided herein describe various layers as comprising a single material, it is understood that combinations of materials, such as a mixture of host and dopant, or more generally a mixture, may be used. Also, the layers may have various sublayers. The names given to the various layers herein are not intended to be strictly limiting. For example, in device 200, hole transport layer 225 transports holes and injects holes into emissive layer 220, and may be described as a hole transport layer or a hole injection layer. In one embodiment, an OLED may be described as having an “organic layer” disposed between a cathode and an anode. This organic layer may comprise a single layer, or may further comprise multiple layers of different organic materials as described, for example, with respect to FIGS. 1 and 2.

Structures and materials not specifically described may also be used, such as OLEDs comprised of polymeric materials (PLEDs) such as disclosed in U.S. Pat. No. 5,247,190 to Friend et al., which is incorporated by reference in its entirety. By way of further example, OLEDs having a single organic layer may be used. OLEDs may be stacked, for example as described in U.S. Pat. No. 5,707,745 to Forrest et al, which is incorporated by reference in its entirety. The OLED structure may deviate from the simple layered structure illustrated in FIGS. 1 and 2. For example, the substrate may include an angled reflective surface to improve outcoupling, such as a mesa structure as described in U.S. Pat. No. 6,091,195 to Forrest et al., and/or a pit structure as described in U.S. Pat. No. 5,834,893 to Bulovic et al., which are incorporated by reference in their entireties.

Unless otherwise specified, any of the layers of the various embodiments may be deposited by any suitable method. For the organic layers, preferred methods include thermal evaporation, ink-jet, such as described in U.S. Pat. Nos. 6,013,982 and 6,087,196, which are incorporated by reference in their entireties, organic vapor phase deposition (OVPD), such as described in U.S. Pat. No. 6,337,102 to Forrest et al., which is incorporated by reference in its entirety, and deposition by organic vapor jet printing (OVJP), such as described in U.S. Pat. No. 7,431,968, which is incorporated by reference in its entirety. Other suitable deposition methods include spin coating and other solution based processes. Solution based processes are preferably carried out in nitrogen or an inert atmosphere. For the other layers, preferred methods include thermal evaporation. Preferred patterning methods include deposition through a mask, cold welding such as described in U.S. Pat. Nos. 6,294,398 and 6,468,819, which are incorporated by reference in their entireties, and patterning associated with some of the deposition methods such as ink-jet and organic vapor jet printing (OVJP). Other methods may also be used. The materials to be deposited may be modified to make them compatible with a particular deposition method. For example, substituents such as alkyl and aryl groups, branched or unbranched, and preferably containing at least 3 carbons, may be used in small molecules to enhance their ability to undergo solution processing. Substituents having 20 carbons or more may be used, and 3-20 carbons are a preferred range. Materials with asymmetric structures may have better solution processability than those having symmetric structures, because asymmetric materials may have a lower tendency to recrystallize. Dendrimer substituents may be used to enhance the ability of small molecules to undergo solution processing.

Devices fabricated in accordance with embodiments of the present disclosure may further optionally comprise a barrier layer. One purpose of the barrier layer is to protect the electrodes and organic layers from damaging exposure to harmful species in the environment including moisture, vapor and/or gases, etc. The barrier layer may be deposited over, under or next to a substrate, an electrode, or over any other parts of a device including an edge. The barrier layer may comprise a single layer, or multiple layers. The barrier layer may be formed by various known chemical vapor deposition techniques and may include compositions having a single phase as well as compositions having multiple phases. Any suitable material or combination of materials may be used for the barrier layer. The barrier layer may incorporate an inorganic or an organic compound or both. The preferred barrier layer comprises a mixture of a polymeric material and a non-polymeric material as described in U.S. Pat. No. 7,968,146, PCT Pat. Application Nos. PCT/US2007/023098 and PCT/US2009/042829, which are herein incorporated by reference in their entireties. To be considered a “mixture”, the aforesaid polymeric and non-polymeric materials comprising the barrier layer should be deposited under the same reaction conditions and/or at the same time. The weight ratio of polymeric to non-polymeric material may be in the range of 95:5 to 5:95. The polymeric material and the non-polymeric material may be created from the same precursor material. In one example, the mixture of a polymeric material and a non-polymeric material consists essentially of polymeric silicon and inorganic silicon.

Devices fabricated in accordance with embodiments of the present disclosure can be incorporated into a wide variety of electronic component modules (or units) that can be incorporated into a variety of electronic products or intermediate components. Examples of such electronic products or intermediate components include display screens, lighting devices such as discrete light source devices or lighting panels, etc. that can be utilized by the end-user product manufacturers. Such electronic component modules can optionally include the driving electronics and/or power source(s). Devices fabricated in accordance with embodiments of the present disclosure can be incorporated into a wide variety of consumer products that have one or more of the electronic component modules (or units) incorporated therein. A consumer product comprising an OLED that includes the compound of the present disclosure in the organic layer in the OLED is disclosed. Such consumer products would include any kind of products that include one or more light source(s) and/or one or more of some type of visual displays. Some examples of such consumer products include flat panel displays, curved displays, computer monitors, medical monitors, televisions, billboards, lights for interior or exterior illumination and/or signaling, heads-up displays, fully or partially transparent displays, flexible displays, rollable displays, foldable displays, stretchable displays, laser printers, telephones, mobile phones, tablets, phablets, personal digital assistants (PDAs), wearable devices, laptop computers, digital cameras, camcorders, viewfinders, micro-displays (displays that are less than 2 inches diagonal), 3-D displays, virtual reality or augmented reality displays, vehicles, video walls comprising multiple displays tiled together, theater or stadium screen, a light therapy device, and a sign. Various control mechanisms may be used to control devices fabricated in accordance with the present disclosure, including passive matrix and active matrix. Many of the devices are intended for use in a temperature range comfortable to humans, such as 18 degrees C. to 30 degrees C., and more preferably at room temperature (20-25° C.), but could be used outside this temperature range, for example, from −40 degree C. to +80° C.

More details on OLEDs, and the definitions described above, can be found in U.S. Pat. No. 7,279,704, which is incorporated herein by reference in its entirety.

The materials and structures described herein may have applications in devices other than OLEDs. For example, other optoelectronic devices such as organic solar cells and organic photodetectors may employ the materials and structures. More generally, organic devices, such as organic transistors, may employ the materials and structures.

In some embodiments, the OLED has one or more characteristics selected from the group consisting of being flexible, being rollable, being foldable, being stretchable, and being curved. In some embodiments, the OLED is transparent or semi-transparent. In some embodiments, the OLED further comprises a layer comprising carbon nanotubes.

In some embodiments, the OLED further comprises a layer comprising a delayed fluorescent emitter. In some embodiments, the OLED comprises a RGB pixel arrangement or white plus color filter pixel arrangement. In some embodiments, the OLED is a mobile device, a hand held device, or a wearable device. In some embodiments, the OLED is a display panel having less than 10 inch diagonal or 50 square inch area. In some embodiments, the OLED is a display panel having at least 10 inch diagonal or 50 square inch area. In some embodiments, the OLED is a lighting panel.

In some embodiments, the compound can be an emissive dopant. In some embodiments, the compound can produce emissions via phosphorescence, fluorescence, thermally activated delayed fluorescence, i.e., TADF (also referred to as E-type delayed fluorescence; see, e.g., U.S. application Ser. No. 15/700,352, which is hereby incorporated by reference in its entirety), triplet-triplet annihilation, or combinations of these processes. In some embodiments, the emissive dopant can be a racemic mixture, or can be enriched in one enantiomer. In some embodiments, the compound can be homoleptic (each ligand is the same). In some embodiments, the compound can be heteroleptic (at least one ligand is different from others). When there are more than one ligand coordinated to a metal, the ligands can all be the same in some embodiments. In some other embodiments, at least one ligand is different from the other ligands. In some embodiments, every ligand can be different from each other. This is also true in embodiments where a ligand being coordinated to a metal can be linked with other ligands being coordinated to that metal to form a tridentate, tetradentate, pentadentate, or hexadentate ligands. Thus, where the coordinating ligands are being linked together, all of the ligands can be the same in some embodiments, and at least one of the ligands being linked can be different from the other ligand(s) in some other embodiments.

In some embodiments, the compound can be used as a phosphorescent sensitizer in an OLED where one or multiple layers in the OLED contains an acceptor in the form of one or more fluorescent and/or delayed fluorescence emitters. In some embodiments, the compound can be used as one component of an exciplex to be used as a sensitizer. As a phosphorescent sensitizer, the compound must be capable of energy transfer to the acceptor and the acceptor will emit the energy or further transfer energy to a final emitter. The acceptor concentrations can range from 0.001% to 100%. The acceptor could be in either the same layer as the phosphorescent sensitizer or in one or more different layers. In some embodiments, the acceptor is a TADF emitter. In some embodiments, the acceptor is a fluorescent emitter. In some embodiments, the emission can arise from any or all of the sensitizer, acceptor, and final emitter

According to another aspect, a formulation comprising the compound described herein is also disclosed.

The OLED disclosed herein can be incorporated into one or more of a consumer product, an electronic component module, and a lighting panel. The organic layer can be an emissive layer and the compound can be an emissive dopant in some embodiments, while the compound can be a non-emissive dopant in other embodiments.

In yet another aspect of the present disclosure, a formulation that comprises the novel compound disclosed herein is described. The formulation can include one or more components selected from the group consisting of a solvent, a host, a hole injection material, hole transport material, electron blocking material, hole blocking material, and an electron transport material, disclosed herein.

The present disclosure encompasses any chemical structure comprising the novel compound of the present disclosure, or a monovalent or polyvalent variant thereof. In other words, the inventive compound, or a monovalent or polyvalent variant thereof, can be a part of a larger chemical structure. Such chemical structure can be selected from the group consisting of a monomer, a polymer, a macromolecule, and a supramolecule (also known as supermolecule). As used herein, a “monovalent variant of a compound” refers to a moiety that is identical to the compound except that one hydrogen has been removed and replaced with a bond to the rest of the chemical structure. As used herein, a “polyvalent variant of a compound” refers to a moiety that is identical to the compound except that more than one hydrogen has been removed and replaced with a bond or bonds to the rest of the chemical structure. In the instance of a supramolecule, the inventive compound can also be incorporated into the supramolecule complex without covalent bonds.

D. Combination of the Compounds of the Present Disclosure with Other Materials

The materials described herein as useful for a particular layer in an organic light emitting device may be used in combination with a wide variety of other materials present in the device. For example, emissive dopants disclosed herein may be used in conjunction with a wide variety of hosts, transport layers, blocking layers, injection layers, electrodes and other layers that may be present. The materials described or referred to below are non-limiting examples of materials that may be useful in combination with the compounds disclosed herein, and one of skill in the art can readily consult the literature to identify other materials that may be useful in combination.

a) Conductivity Dopants:

A charge transport layer can be doped with conductivity dopants to substantially alter its density of charge carriers, which will in turn alter its conductivity. The conductivity is increased by generating charge carriers in the matrix material, and depending on the type of dopant, a change in the Fermi level of the semiconductor may also be achieved. Hole-transporting layer can be doped by p-type conductivity dopants and n-type conductivity dopants are used in the electron-transporting layer.

Non-limiting examples of the conductivity dopants that may be used in an OLED in combination with materials disclosed herein are exemplified below together with references that disclose those materials: EP01617493, EP01968131, EP2020694, EP2684932, US20050139810, US20070160905, US20090167167, US2010288362, WO06081780, WO2009003455, WO2009008277, WO2009011327, WO2014009310, US2007252140, US2015060804, US20150123047, and US2012146012.

b) HIL/HTL:

A hole injecting/transporting material to be used in the present disclosure is not particularly limited, and any compound may be used as long as the compound is typically used as a hole injecting/transporting material. Examples of the material include, but are not limited to: a phthalocyanine or porphyrin derivative; an aromatic amine derivative; an indolocarbazole derivative; a polymer containing fluorohydrocarbon; a polymer with conductivity dopants; a conducting polymer, such as PEDOT/PSS; a self-assembly monomer derived from compounds such as phosphonic acid and silane derivatives; a metal oxide derivative, such as MoO_(x); a p-type semiconducting organic compound, such as 1,4,5,8,9,12-Hexaazatriphenylenehexacarbonitrile; a metal complex, and a cross-linkable compounds.

HIL/HTL examples can be found in paragraphs [0111] through [0117] of Universal Display Corporation's US application publication number US2020/0,295,281A1, and the contents of these paragraphs and the whole publication are herein incorporated by reference in their entireties.

c) EBL:

An electron blocking layer (EBL) may be used to reduce the number of electrons and/or excitons that leave the emissive layer. The presence of such a blocking layer in a device may result in substantially higher efficiencies, and/or longer lifetime, as compared to a similar device lacking a blocking layer. Also, a blocking layer may be used to confine emission to a desired region of an OLED. In some embodiments, the EBL material has a higher LUMO (closer to the vacuum level) and/or higher triplet energy than the emitter closest to the EBL interface. In some embodiments, the EBL material has a higher LUMO (closer to the vacuum level) and/or higher triplet energy than one or more of the hosts closest to the EBL interface. In one aspect, the compound used in EBL contains the same molecule or the same functional groups used as one of the hosts described below.

d) Hosts:

The light emitting layer of the organic EL device of the present disclosure preferably contains at least a metal complex as light emitting material, and may contain a host material using the metal complex as a dopant material. Examples of the host material are not particularly limited, and any metal complexes or organic compounds may be used as long as the triplet energy of the host is larger than that of the dopant. Any host material may be used with any dopant so long as the triplet criteria is satisfied.

Hosts examples can be found in paragraphs [0119] through [0125] of Universal Display Corporation's US application publication number US2020/0,295,281A1, and the contents of these paragraphs and the whole publication are herein incorporated by reference in their entireties.

e) Additional Emitters:

One or more additional emitter dopants may be used in conjunction with the compound of the present disclosure. Examples of the additional emitter dopants are not particularly limited, and any compounds may be used as long as the compounds are typically used as emitter materials. Examples of suitable emitter materials include, but are not limited to, compounds which can produce emissions via phosphorescence, fluorescence, thermally activated delayed fluorescence, i.e., TADF (also referred to as E-type delayed fluorescence), triplet-triplet annihilation, or combinations of these processes.

Non-limiting examples of the emitter materials that may be used in an OLED in combination with materials disclosed herein are exemplified in paragraphs [0126] through [0127] of Universal Display Corporation's US application publication number US2020/0,295,281A1, and the contents of these paragraphs and the whole publication are herein incorporated by reference in their entireties.

f) HBL:

A hole blocking layer (HBL) may be used to reduce the number of holes and/or excitons that leave the emissive layer. The presence of such a blocking layer in a device may result in substantially higher efficiencies and/or longer lifetime as compared to a similar device lacking a blocking layer. Also, a blocking layer may be used to confine emission to a desired region of an OLED. In some embodiments, the HBL material has a lower HOMO (further from the vacuum level) and/or higher triplet energy than the emitter closest to the HBL interface. In some embodiments, the HBL material has a lower HOMO (further from the vacuum level) and/or higher triplet energy than one or more of the hosts closest to the HBL interface.

In one aspect, compound used in HBL contains the same molecule or the same functional groups used as host described above.

In another aspect, compound used in HBL contains at least one of the following groups in the molecule:

wherein k is an integer from 1 to 20; L¹⁰¹ is another ligand, k′ is an integer from 1 to 3.

g) ETL:

Electron transport layer (ETL) may include a material capable of transporting electrons. Electron transport layer may be intrinsic (undoped), or doped. Doping may be used to enhance conductivity. Examples of the ETL material are not particularly limited, and any metal complexes or organic compounds may be used as long as they are typically used to transport electrons.

In one aspect, compound used in ETL contains at least one of the following groups in the molecule:

wherein R¹⁰¹ is selected from the group consisting of hydrogen, deuterium, halogen, alkyl, cycloalkyl, heteroalkyl, heterocycloalkyl, arylalkyl, alkoxy, aryloxy, amino, silyl, alkenyl, cycloalkenyl, heteroalkenyl, alkynyl, aryl, heteroaryl, acyl, carboxylic acids, ether, ester, nitrile, isonitrile, sulfanyl, sulfinyl, sulfonyl, phosphino, and combinations thereof, when it is aryl or heteroaryl, it has the similar definition as Ar's mentioned above. Ar¹ to Ar³ has the similar definition as Ar's mentioned above. k is an integer from 1 to 20. X¹⁰¹ to X¹⁰⁸ is selected from C (including CH) or N.

In another aspect, the metal complexes used in ETL contains, but not limit to the following general formula:

wherein (O—N) or (N—N) is a bidentate ligand, having metal coordinated to atoms O, N or N, N; L¹⁰¹ is another ligand; k′ is an integer value from 1 to the maximum number of ligands that may be attached to the metal. Non-limiting examples of the ETL materials that may be used in an OLED in combination with materials disclosed herein are exemplified in paragraphs [0131] through [0134] of Universal Display Corporation's US application publication number US2020/0,295,281A1, and the contents of these paragraphs and the whole publication are herein incorporated by reference in their entireties.

h) Charge Generation Layer (CGL)

In tandem or stacked OLEDs, the CGL plays an essential role in the performance, which is composed of an n-doped layer and a p-doped layer for injection of electrons and holes, respectively. Electrons and holes are supplied from the CGL and electrodes. The consumed electrons and holes in the CGL are refilled by the electrons and holes injected from the cathode and anode, respectively; then, the bipolar currents reach a steady state gradually. Typical CGL materials include n and p conductivity dopants used in the transport layers.

In any above-mentioned compounds used in each layer of the OLED device, the hydrogen atoms can be partially or fully deuterated. The minimum amount of hydrogen of the compound being deuterated is selected from the group consisting of 30%, 40%, 50%, 60%, 70%, 80%, 90%, 95%, 99%, and 100%. Thus, any specifically listed substituent, such as, without limitation, methyl, phenyl, pyridyl, etc. may be undeuterated, partially deuterated, and fully deuterated versions thereof. Similarly, classes of substituents such as, without limitation, alkyl, aryl, cycloalkyl, heteroaryl, etc. also may be undeuterated, partially deuterated, and fully deuterated versions thereof.

It is understood that the various embodiments described herein are by way of example only and are not intended to limit the scope of the invention. For example, many of the materials and structures described herein may be substituted with other materials and structures without deviating from the spirit of the invention. The present invention as claimed may therefore include variations from the particular examples and preferred embodiments described herein, as will be apparent to one of skill in the art. It is understood that various theories as to why the invention works are not intended to be limiting.

E. Experimental Section

Synthesis of 8-bromo-2-((2-(trimethylsilyl)ethoxy)methyl)isoquinolin-1(2H)-one

Sodium tert-butoxide solution (2.0 Min THF, 34 mL, 68 mmol) was added to a stirred suspension of 8-bromoisoquinolin-1(2H)-one (10.2 g, 45.5 mmol) in anhydrous THF (200 mL) at 0° C. under N₂. The mixture was stirred at 0° C. for 30 min, then SEM-Cl (16 mL, 91 mmol) was added. The mixture was allowed to warm to room temperature (RT) and stirred for 2 hours. The reaction mixture was partitioned between sat. NaHCO₃ (aq) (200 mL) and EtOAc (100 mL). The layers were separated and the aqueous layer was extracted with EtOAc (100 mL). The combined organic layers were washed with brine (200 mL), dried over MgSO₄, filtered and concentrated. The residue was loaded onto silica and purified by flash column chromatography (silica gel, 0-60% EtOAc/isohexane) to afford 8-bromo-2-((2-(trimethylsilyl)ethoxy)methyl)isoquinolin-1(2H)-one (11.9 g, 33.6 mmol, 74% yield) as a colourless solid.

Synthesis of 8-(prop-1-en-2-yl)-2-((2-(trimethylsilyl)ethoxy)methyl)isoquinolin-1(2H)-one

A flask was charged with 8-bromo-2-((2-(trimethylsilyl)ethoxy)methyl)isoquinolin-1(2H)-one (7.53 g, 21.3 mmol), 4,4,5,5-tetramethyl-2-(prop-1-en-2-yl)-1,3,2-dioxaborolane (8.0 mL, 43 mmol), Pd(PPh₃)₄ (1.23 g, 1.06 mmol), cesium carbonate (20.8 g, 63.8 mmol), THF (85 mL) and water (21 mL). The mixture was sparged with N₂ for 20 min then stirred at 80° C. for 20 hours. After cooling, the mixture was partitioned between EtOAc (100 mL) and water (200 mL). The aqueous was separated and the organic phase was washed with brine (200 mL), dried over MgSO₄, filtered and concentrated. The residue was purified by flash column chromatography (silica gel, 0-60% EtOAc/isohexane) to afford 8-(prop-1-en-2-yl)-2-((2-(trimethylsilyl)ethoxy)methyl) isoquinolin-1(2H)-one (5.10 g, 16.0 mmol, 75% yield) as a colourless oil.

Synthesis of 3-Methyl-1-(tetrahydro-2H-pyran-2-yl)-1H-pyrazole

A flask was charged with 3-methyl-1H-pyrazole (9.8 mL, 120 mmol), 3,4-dihydro-2H-pyran (35 mL, 380 mmol) and TFA (0.47 mL, 6.1 mmol). The mixture was heated to 75° C. and stirred for 4 hours. After cooling the mixture was diluted with TBME (150 mL) and transferred to a separatory funnel. The organic layer was washed with sat. NaHCO₃ (aq) (150 mL) and brine (150 mL), dried over MgSO₄, filtered and concentrated. The residue was purified by flash column chromatography (silica, 0-80% TBME/isohexane) to afford 3-methyl-1-(tetrahydro-2H-pyran-2-yl)-1H-pyrazole (3) (19.0 g, 93.0 mmol, 76% yield) as a colourless oil.

Synthesis of 7,7,10-Trimethyl-7H-benzo[de]pyrazolo[1,5-h][1,7]naphthyridine

n-BuLi (2.5M in hexanes, 14.2 mL, 35.6 mmol) was added dropwise to a stirred solution of 3-methyl-1-(tetrahydro-2H-pyran-2-yl)-1H-pyrazole (7.05 g, 33.9 mmol) in anhydrous THF (100 mL) at −78° C. under N₂. After stirring for 15 min a solution of 8-(prop-1-en-2-yl)-2-((2-(trimethylsilyl)ethoxy)methyl) isoquinolin-1(2H)-one (5.10 g, 16.17 mmol) in anhydrous THF (60 mL) was added over 5 min. The mixture was allowed to warm to RT and stirred for 18 hours. The volatiles were removed in vacuo and the residue was dissolved in MeOH (20 mL). 4 M HCl in 1,4-dioxane (40 mL) was added, the mixture heated to 50° C. and stirred for 2 hours. After cooling the mixture was partitioned between EtOAc (100 mL) and 2 M NaOH(aq) (100 mL). The layers were separated and the aqueous layer was extracted with EtOAc (2×100 mL). The combined organic layers were washed with brine (250 mL), dried over MgSO₄, filtered and concentrated. The residue was purified by flash column chromatography (silica gel, 0-100% EtOAc/DCM) to afford 7,7,10-trimethyl-7H-benzo[de]pyrazolo[1,5-h][1,7] naphthyridine (4) (1.54 g, 6.12 mmol, 38% yield) as an orange solid.

Synthesis of Inventive Example

A solution of 7,7,10-trimethyl-7H-benzo[de]pyrazolo[1,5-h][1,7]naphthyridine (1.40 g, 5.62 mmol), and iridium(III) chloride hydrate (0.990 g, 2.81 mmol) was degassed under N₂ for 10 mins. The reaction was heated at 130° C. for 18 hours. The flask was cooled to RT, and 0.330 g of iridium(III) chloride hydrate was added. The reaction was heated at 130° C. for another 18 hours. The reaction flask was cooled to RT, and 3,7-diethylnonane-4,6-dione (1.193 g, 5.62 mmol), and K₂CO₃ (0.776 g, 5.62 mmol), and 1,4-Dioxane (28 ml) was added. The mixture was stirred at 80° C. for 2 days. The reaction flask was cooled to RT, and the volatiles were removed under vacuum. The crude was purified by column chromatography, eluting with EtOAc/DCM (40 to 60% EtOAc). The product was isolated as a dark red solid (0.18 g, 2.81 mmol, 7% yield).

FIG. 3 shows photoluminescence (PL) spectrum of the inventive example compound taken in 2-MeTHF at RT. The PL intensity is normalized to the maximum of the emission peak. The emission maximum of the inventive example compound is 691 nm, indicating its great potential as phosphorescent emitters. 

What is claimed is:
 1. A compound comprising a ligand L_(A) having a structure of

wherein: one of Z¹ and Z² is C and the other is N; each of K¹ or K² is independently a direct bond, O, or S; moiety B, moiety C, and moiety D are each independently monocyclic or polycyclic ring structure containing 5-membered or 6-membered carbocyclic or heterocyclic rings; X¹-X⁴ are each independently C or N, with at least one of X¹ or X² being N if both moiety B and moiety C of Formula I are monocyclic 6-membered aromatic rings; Y is selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; W is selected from the group consisting of O, S, S═O, SO₂, NR, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, GeRR′, PR, P═O, and P═S; each of R^(A), R^(B), R^(C), and R^(D) independently represents zero, mono, or up to a maximum allowed number of substitutions to its associated ring; each of R, R′, R^(A), R^(B), R^(C), and R^(D) is independently a hydrogen or a substituent selected from the group consisting of deuterium, halogen, alkyl, cycloalkyl, heteroalkyl, heterocycloalkyl, arylalkyl, alkoxy, aryloxy, amino, silyl, germyl, boryl, selenyl, alkenyl, cycloalkenyl, heteroalkenyl, alkynyl, aryl, heteroaryl, acyl, carboxylic acid, ether, ester, nitrile, isonitrile, sulfanyl, sulfinyl, sulfonyl, phosphino, and combinations thereof; and any two adjacent R, R′, R^(A), R^(B), R^(C), or R^(D) can be joined or fused together to form a ring, wherein the ligand L_(A) is coordinated to a metal M by the two indicated dashed lines; wherein M is selected from the group consisting of Ru, Os, Ir, Pd, Pt, Cu, Ag, and Au; and wherein the ligand L_(A) can be joined with other ligands to form a tridentate, tetradentate, pentadentate, or hexadentate ligand.
 2. The compound of claim 1, wherein each of R, R′, R^(A), R^(B), R^(C), and R^(D) is independently a hydrogen or a substituent selected from the group consisting of deuterium, fluorine, alkyl, cycloalkyl, heteroalkyl, alkoxy, aryloxy, amino, silyl, boryl, alkenyl, cycloalkenyl, heteroalkenyl, aryl, heteroaryl, nitrile, isonitrile, sulfanyl, and combinations thereof.
 3. The compound of claim 1, wherein W is O, S, NR, CRR′, BR, BRR′, or SiRR′.
 4. The compound of claim 1, wherein Y is O, S, NR, BR, or BRR′.
 5. The compound of claim 1, wherein X¹ is C; or X² is C; or one of X¹ and X² is C and the other is N; or X¹ and X² are both C while one of moiety B or moiety C of Formula I is a 5-membered ring.
 6. The compound of claim 1, wherein X³ and X⁴ are both C, or X³ is C, and X⁴ is N.
 7. The compound of claim 1, wherein moiety B or moiety D is a 5-membered or 6-membered aromatic ring.
 8. The compound of claim 1, wherein moiety C each is independently a monocyclic 5-membered or 6-membered aromatic ring, or a multicyclic ring structure containing a total of two, three, four, five, six or seven fused rings containing 5-membered and 6-membered aromatic rings.
 9. The compound of claim 1, wherein the ligand L_(A) is selected from the group consisting of:

wherein X⁵, X⁶, and X⁷ are each independently C or N; Y² for each occurrence is independently selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; and each of ring A1 and ring B1 is independently a 5-membered or 6-membered carbocyclic or heterocyclic ring.
 10. The compound of claim 1, wherein the ligand L_(A) is selected from the group consisting of:

wherein: X⁵-X¹⁰ are each independently N or C; Y¹ is O, S, or Se; Y² for each occurrence is independently selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; and R, R′, and the remaining variables are the same as previously defined.
 11. The compound of claim 1, wherein the ligand L_(A) is selected from the group consisting of L_(Ai-m) wherein i=1 to 1560, m=1 to 18, and based on formula L_(Ai-1) to L_(Ai-18); L_(Ai-m′) wherein i=1 to 4420, m′=19 to 54, and based on formula L_(Ai-19) to L_(Ai-54); and L_(Ai′-m″) wherein i′=4421 to 4740, m″=55 to 69, and based on formula L_(Ai′-55) to L_(Ai′-69), wherein each structure of L_(Ai-1) through L_(Ai-54), and L_(Ai′-55) through L_(Ai′-69) is defined as follows:

wherein for each i in L_(Ai), and L_(Ai′), R^(E), G, and W are defined below: i R^(E) G W 1 R¹ G¹¹ W¹ 2 R² G¹¹ W¹ 3 R⁴ G¹¹ W¹ 4 R⁵ G¹¹ W¹ 5 R⁷ G¹¹ W¹ 6 R⁸ G¹¹ W¹ 7 R¹⁰ G¹¹ W¹ 8 R¹² G¹¹ W¹ 9 R¹⁴ G¹¹ W¹ 10 R¹⁵ G¹¹ W¹ 11 R¹⁹ G¹¹ W¹ 12 R²⁷ G¹¹ W¹ 13 R²⁸ G¹¹ W¹ 14 R³³ G¹¹ W¹ 15 R³⁸ G¹¹ W¹ 16 R³⁹ G¹¹ W¹ 17 R⁴¹ G¹¹ W¹ 18 R⁴⁶ G¹¹ W¹ 19 R⁴⁷ G¹¹ W¹ 20 R⁴⁹ G¹¹ W¹ 21 R¹ G¹² W¹ 22 R² G¹² W¹ 23 R⁴ G¹² W¹ 24 R⁵ G¹² W¹ 25 R⁷ G¹² W¹ 26 R⁸ G¹² W¹ 27 R¹⁰ G¹² W¹ 28 R¹² G¹² W¹ 29 R¹⁴ G¹² W¹ 30 R¹⁵ G¹² W¹ 31 R¹⁹ G¹² W¹ 32 R²⁷ G¹² W¹ 33 R²⁸ G¹² W¹ 34 R³³ G¹² W¹ 35 R³⁸ G¹² W¹ 36 R³⁹ G¹² W¹ 37 R⁴¹ G¹² W¹ 38 R⁴⁶ G¹² W¹ 39 R⁴⁷ G¹² W¹ 40 R⁴⁹ G¹² W¹ 41 R¹ G¹³ W¹ 42 R² G¹³ W¹ 43 R⁴ G¹³ W¹ 44 R⁵ G¹³ W¹ 45 R⁷ G¹³ W¹ 46 R⁸ G¹³ W¹ 47 R¹⁰ G¹³ W¹ 48 R¹² G¹³ W¹ 49 R¹⁴ G¹³ W¹ 50 R¹⁵ G¹³ W¹ 51 R¹⁹ G¹³ W¹ 52 R²⁷ G¹³ W¹ 53 R²⁸ G¹³ W¹ 54 R³³ G¹³ W¹ 55 R³⁸ G¹³ W¹ 56 R³⁹ G¹³ W¹ 57 R⁴¹ G¹³ W¹ 58 R⁴⁶ G¹³ W¹ 59 R⁴⁷ G¹³ W¹ 60 R⁴⁹ G¹³ W¹ 61 R¹ G¹⁶ W¹ 62 R² G¹⁶ W¹ 63 R⁴ G¹⁶ W¹ 64 R⁵ G¹⁶ W¹ 65 R⁷ G¹⁶ W¹ 66 R⁸ G¹⁶ W¹ 67 R¹⁰ G¹⁶ W¹ 68 R¹² G¹⁶ W¹ 69 R¹⁴ G¹⁶ W¹ 70 R¹⁵ G¹⁶ W¹ 71 R¹⁹ G¹⁶ W¹ 72 R²⁷ G¹⁶ W¹ 73 R²⁸ G¹⁶ W¹ 74 R³³ G¹⁶ W¹ 75 R³⁸ G¹⁶ W¹ 76 R³⁹ G¹⁶ W¹ 77 R⁴¹ G¹⁶ W¹ 78 R⁴⁶ G¹⁶ W¹ 79 R⁴⁷ G¹⁶ W¹ 80 R⁴⁹ G¹⁶ W¹ 81 R¹ G¹⁷ W¹ 82 R² G¹⁷ W¹ 83 R⁴ G¹⁷ W¹ 84 R⁵ G¹⁷ W¹ 85 R⁷ G¹⁷ W¹ 86 R⁸ G¹⁷ W¹ 87 R¹⁰ G¹⁷ W¹ 88 R¹² G¹⁷ W¹ 89 R¹⁴ G¹⁷ W¹ 90 R¹⁵ G¹⁷ W¹ 91 R¹⁹ G¹⁷ W¹ 92 R²⁷ G¹⁷ W¹ 93 R²⁸ G¹⁷ W¹ 94 R³³ G¹⁷ W¹ 95 R³⁸ G¹⁷ W¹ 96 R³⁹ G¹⁷ W¹ 97 R⁴¹ G¹⁷ W¹ 98 R⁴⁶ G¹⁷ W¹ 99 R⁴⁷ G¹⁷ W¹ 100 R⁴⁹ G¹⁷ W¹ 101 R¹ G¹⁸ W¹ 102 R² G¹⁸ W¹ 103 R⁴ G¹⁸ W¹ 104 R⁵ G¹⁸ W¹ 105 R⁷ G¹⁸ W¹ 106 R⁸ G¹⁸ W¹ 107 R¹⁰ G¹⁸ W¹ 108 R¹² G¹⁸ W¹ 109 R¹⁴ G¹⁸ W¹ 110 R¹⁵ G¹⁸ W¹ 111 R¹⁹ G¹⁸ W¹ 112 R²⁷ G¹⁸ W¹ 113 R²⁸ G¹⁸ W¹ 114 R³³ G¹⁸ W¹ 115 R³⁸ G¹⁸ W¹ 116 R³⁹ G¹⁸ W¹ 117 R⁴¹ G¹⁸ W¹ 118 R⁴⁶ G¹⁸ W¹ 119 R⁴⁷ G¹⁸ W¹ 120 R⁴⁹ G¹⁸ W¹ 121 R¹ G²¹ W¹ 122 R² G²¹ W¹ 123 R⁴ G²¹ W¹ 124 R⁵ G²¹ W¹ 125 R⁷ G²¹ W¹ 126 R⁸ G²¹ W¹ 127 R¹⁰ G²¹ W¹ 128 R¹² G²¹ W¹ 129 R¹⁴ G²¹ W¹ 130 R¹⁵ G²¹ W¹ 131 R¹⁹ G²¹ W¹ 132 R²⁷ G²¹ W¹ 133 R²⁸ G²¹ W¹ 134 R³³ G²¹ W¹ 135 R³⁸ G²¹ W¹ 136 R³⁹ G²¹ W¹ 137 R⁴¹ G²¹ W¹ 138 R⁴⁶ G²¹ W¹ 139 R⁴⁷ G²¹ W¹ 140 R⁴⁹ G²¹ W¹ 141 R¹ G²² W¹ 142 R² G²² W¹ 143 R⁴ G²² W¹ 144 R⁵ G²² W¹ 145 R⁷ G²² W¹ 146 R⁸ G²² W¹ 147 R¹⁰ G²² W¹ 148 R¹² G²² W¹ 149 R¹⁴ G²² W¹ 150 R¹⁵ G²² W¹ 151 R¹⁹ G²² W¹ 152 R²⁷ G²² W¹ 153 R²⁸ G²² W¹ 154 R³³ G²² W¹ 155 R³⁸ G²² W¹ 156 R³⁹ G²² W¹ 157 R⁴¹ G²² W¹ 158 R⁴⁶ G²² W¹ 159 R⁴⁷ G²² W¹ 160 R⁴⁹ G²² W¹ 161 R¹ G²³ W¹ 162 R² G²³ W¹ 163 R⁴ G²³ W¹ 164 R⁵ G²³ W¹ 165 R⁷ G²³ W¹ 166 R⁸ G²³ W¹ 167 R¹⁰ G²³ W¹ 168 R¹² G²³ W¹ 169 R¹⁴ G²³ W¹ 170 R¹⁵ G²³ W¹ 171 R¹⁹ G²³ W¹ 172 R²⁷ G²³ W¹ 173 R²⁸ G²³ W¹ 174 R³³ G²³ W¹ 175 R³⁸ G²³ W¹ 176 R³⁹ G²³ W¹ 177 R⁴¹ G²³ W¹ 178 R⁴⁶ G²³ W¹ 179 R⁴⁷ G²³ W¹ 180 R⁴⁹ G²³ W¹ 181 R¹ G²⁴ W¹ 182 R² G²⁴ W¹ 183 R⁴ G²⁴ W¹ 184 R⁵ G²⁴ W¹ 185 R⁷ G²⁴ W¹ 186 R⁸ G²⁴ W¹ 187 R¹⁰ G²⁴ W¹ 188 R¹² G²⁴ W¹ 189 R¹⁴ G²⁴ W¹ 190 R¹⁵ G²⁴ W¹ 191 R¹⁹ G²⁴ W¹ 192 R²⁷ G²⁴ W¹ 193 R²⁸ G²⁴ W¹ 194 R³³ G²⁴ W¹ 195 R³⁸ G²⁴ W¹ 196 R³⁹ G²⁴ W¹ 197 R⁴¹ G²⁴ W¹ 198 R⁴⁶ G²⁴ W¹ 199 R⁴⁷ G²⁴ W¹ 200 R⁴⁹ G²⁴ W¹ 201 R¹ G¹¹ W¹¹ 202 R² G¹¹ W¹¹ 203 R⁴ G¹¹ W¹¹ 204 R⁵ G¹¹ W¹¹ 205 R⁷ G¹¹ W¹¹ 206 R⁸ G¹¹ W¹¹ 207 R¹⁰ G¹¹ W¹¹ 208 R¹² G¹¹ W¹¹ 209 R¹⁴ G¹¹ W¹¹ 210 R¹⁵ G¹¹ W¹¹ 211 R¹⁹ G¹¹ W¹¹ 212 R²⁷ G¹¹ W¹¹ 213 R²⁸ G¹¹ W¹¹ 214 R³³ G¹¹ W¹¹ 215 R³⁸ G¹¹ W¹¹ 216 R³⁹ G¹¹ W¹¹ 217 R⁴¹ G¹¹ W¹¹ 218 R⁴⁶ G¹¹ W¹¹ 219 R⁴⁷ G¹¹ W¹¹ 220 R⁴⁹ G¹¹ W¹¹ 221 R¹ G¹² W¹¹ 222 R² G¹² W¹¹ 223 R⁴ G¹² W¹¹ 224 R⁵ G¹² W¹¹ 225 R⁷ G¹² W¹¹ 226 R⁸ G¹² W¹¹ 227 R¹⁰ G¹² W¹¹ 228 R¹² G¹² W¹¹ 229 R¹⁴ G¹² W¹¹ 230 R¹⁵ G¹² W¹¹ 231 R¹⁹ G¹² W¹¹ 232 R²⁷ G¹² W¹¹ 233 R²⁸ G¹² W¹¹ 234 R³³ G¹² W¹¹ 235 R³⁸ G¹² W¹¹ 236 R³⁹ G¹² W¹¹ 237 R⁴¹ G¹² W¹¹ 238 R⁴⁶ G¹² W¹¹ 239 R⁴⁷ G¹² W¹¹ 240 R⁴⁹ G¹² W¹¹ 241 R¹ G¹³ W¹¹ 242 R² G¹³ W¹¹ 243 R⁴ G¹³ W¹¹ 244 R⁵ G¹³ W¹¹ 245 R⁷ G¹³ W¹¹ 246 R⁸ G¹³ W¹¹ 247 R¹⁰ G¹³ W¹¹ 248 R¹² G¹³ W¹¹ 249 R¹⁴ G¹³ W¹¹ 250 R¹⁵ G¹³ W¹¹ 251 R¹⁹ G¹³ W¹¹ 252 R²⁷ G¹³ W¹¹ 253 R²⁸ G¹³ W¹¹ 254 R³³ G¹³ W¹¹ 255 R³⁸ G¹³ W¹¹ 256 R³⁹ G¹³ W¹¹ 257 R⁴¹ G¹³ W¹¹ 258 R⁴⁶ G¹³ W¹¹ 259 R⁴⁷ G¹³ W¹¹ 260 R⁴⁹ G¹³ W¹¹ 261 R¹ G¹⁶ W¹¹ 262 R² G¹⁶ W¹¹ 263 R⁴ G¹⁶ W¹¹ 264 R⁵ G¹⁶ W¹¹ 265 R⁷ G¹⁶ W¹¹ 266 R⁸ G¹⁶ W¹¹ 267 R¹⁰ G¹⁶ W¹¹ 268 R¹² G¹⁶ W¹¹ 269 R¹⁴ G¹⁶ W¹¹ 270 R¹⁵ G¹⁶ W¹¹ 271 R¹⁹ G¹⁶ W¹¹ 272 R²⁷ G¹⁶ W¹¹ 273 R²⁸ G¹⁶ W¹¹ 274 R³³ G¹⁶ W¹¹ 275 R³⁸ G¹⁶ W¹¹ 276 R³⁹ G¹⁶ W¹¹ 277 R⁴¹ G¹⁶ W¹¹ 278 R⁴⁶ G¹⁶ W¹¹ 279 R⁴⁷ G¹⁶ W¹¹ 280 R⁴⁹ G¹⁶ W¹¹ 281 R¹ G¹⁷ W¹¹ 282 R² G¹⁷ W¹¹ 283 R⁴ G¹⁷ W¹¹ 284 R⁵ G¹⁷ W¹¹ 285 R⁷ G¹⁷ W¹¹ 286 R⁸ G¹⁷ W¹¹ 287 R¹⁰ G¹⁷ W¹¹ 288 R¹² G¹⁷ W¹¹ 289 R¹⁴ G¹⁷ W¹¹ 290 R¹⁵ G¹⁷ W¹¹ 291 R¹⁹ G¹⁷ W¹¹ 292 R²⁷ G¹⁷ W¹¹ 293 R²⁸ G¹⁷ W¹¹ 294 R³³ G¹⁷ W¹¹ 295 R³⁸ G¹⁷ W¹¹ 296 R³⁹ G¹⁷ W¹¹ 297 R⁴¹ G¹⁷ W¹¹ 298 R⁴⁶ G¹⁷ W¹¹ 299 R⁴⁷ G¹⁷ W¹¹ 300 R⁴⁹ G¹⁷ W¹¹ 301 R¹ G¹⁸ W¹¹ 302 R² G¹⁸ W¹¹ 303 R⁴ G¹⁸ W¹¹ 304 R⁵ G¹⁸ W¹¹ 305 R⁷ G¹⁸ W¹¹ 306 R⁸ G¹⁸ W¹¹ 307 R¹⁰ G¹⁸ W¹¹ 308 R¹² G¹⁸ W¹¹ 309 R¹⁴ G¹⁸ W¹¹ 310 R¹⁵ G¹⁸ W¹¹ 311 R¹⁹ G¹⁸ W¹¹ 312 R²⁷ G¹⁸ W¹¹ 313 R²⁸ G¹⁸ W¹¹ 314 R³³ G¹⁸ W¹¹ 315 R³⁸ G¹⁸ W¹¹ 316 R³⁹ G¹⁸ W¹¹ 317 R⁴¹ G¹⁸ W¹¹ 318 R⁴⁶ G¹⁸ W¹¹ 319 R⁴⁷ G¹⁸ W¹¹ 320 R⁴⁹ G¹⁸ W¹¹ 321 R¹ G²¹ W¹¹ 322 R² G²¹ W¹¹ 323 R⁴ G²¹ W¹¹ 324 R⁵ G²¹ W¹¹ 325 R⁷ G²¹ W¹¹ 326 R⁸ G²¹ W¹¹ 327 R¹⁰ G²¹ W¹¹ 328 R¹² G²¹ W¹¹ 329 R¹⁴ G²¹ W¹¹ 330 R¹⁵ G²¹ W¹¹ 331 R¹⁹ G²¹ W¹¹ 332 R²⁷ G²¹ W¹¹ 333 R²⁸ G²¹ W¹¹ 334 R³³ G²¹ W¹¹ 335 R³⁸ G²¹ W¹¹ 336 R³⁹ G²¹ W¹¹ 337 R⁴¹ G²¹ W¹¹ 338 R⁴⁶ G²¹ W¹¹ 339 R⁴⁷ G²¹ W¹¹ 340 R⁴⁹ G²¹ W¹¹ 341 R¹ G²² W¹¹ 342 R² G²² W¹¹ 343 R⁴ G²² W¹¹ 344 R⁵ G²² W¹¹ 345 R⁷ G²² W¹¹ 346 R⁸ G²² W¹¹ 347 R¹⁰ G²² W¹¹ 348 R¹² G²² W¹¹ 349 R¹⁴ G²² W¹¹ 350 R¹⁵ G²² W¹¹ 351 R¹⁹ G²² W¹¹ 352 R²⁷ G²² W¹¹ 353 R²⁸ G²² W¹¹ 354 R³³ G²² W¹¹ 355 R³⁸ G²² W¹¹ 356 R³⁹ G²² W¹¹ 357 R⁴¹ G²² W¹¹ 358 R⁴⁶ G²² W¹¹ 359 R⁴⁷ G²² W¹¹ 360 R⁴⁹ G²² W¹¹ 361 R¹ G²³ W¹¹ 362 R² G²³ W¹¹ 363 R⁴ G²³ W¹¹ 364 R⁵ G²³ W¹¹ 365 R⁷ G²³ W¹¹ 366 R⁸ G²³ W¹¹ 367 R¹⁰ G²³ W¹¹ 368 R¹² G²³ W¹¹ 369 R¹⁴ G²³ W¹¹ 370 R¹⁵ G²³ W¹¹ 371 R¹⁹ G²³ W¹¹ 372 R²⁷ G²³ W¹¹ 373 R²⁸ G²³ W¹¹ 374 R³³ G²³ W¹¹ 375 R³⁸ G²³ W¹¹ 376 R³⁹ G²³ W¹¹ 377 R⁴¹ G²³ W¹¹ 378 R⁴⁶ G²³ W¹¹ 379 R⁴⁷ G²³ W¹¹ 380 R⁴⁹ G²³ W¹¹ 381 R¹ G²⁴ W¹¹ 382 R² G²⁴ W¹¹ 383 R⁴ G²⁴ W¹¹ 384 R⁵ G²⁴ W¹¹ 385 R⁷ G²⁴ W¹¹ 386 R⁸ G²⁴ W¹¹ 387 R¹⁰ G²⁴ W¹¹ 388 R¹² G²⁴ W¹¹ 389 R¹⁴ G²⁴ W¹¹ 390 R¹⁵ G²⁴ W¹¹ 391 R¹⁹ G²⁴ W¹¹ 392 R²⁷ G²⁴ W¹¹ 393 R²⁸ G²⁴ W¹¹ 394 R³³ G²⁴ W¹¹ 395 R³⁸ G²⁴ W¹¹ 396 R³⁹ G²⁴ W¹¹ 397 R⁴¹ G²⁴ W¹¹ 398 R⁴⁶ G²⁴ W¹¹ 399 R⁴⁷ G²⁴ W¹¹ 400 R⁴⁹ G²⁴ W¹¹ 401 R¹ G¹¹ W²¹ 402 R² G¹¹ W²¹ 403 R⁴ G¹¹ W²¹ 404 R⁵ G¹¹ W²¹ 405 R⁷ G¹¹ W²¹ 406 R⁸ G¹¹ W²¹ 407 R¹⁰ G¹¹ W²¹ 408 R¹² G¹¹ W²¹ 409 R¹⁴ G¹¹ W²¹ 410 R¹⁵ G¹¹ W²¹ 411 R¹⁹ G¹¹ W²¹ 412 R²⁷ G¹¹ W²¹ 413 R²⁸ G¹¹ W²¹ 414 R³³ G¹¹ W²¹ 415 R³⁸ G¹¹ W²¹ 416 R³⁹ G¹¹ W²¹ 417 R⁴¹ G¹¹ W²¹ 418 R⁴⁶ G¹¹ W²¹ 419 R⁴⁷ G¹¹ W²¹ 420 R⁴⁹ G¹¹ W²¹ 421 R¹ G¹² W²¹ 422 R² G¹² W²¹ 423 R⁴ G¹² W²¹ 424 R⁵ G¹² W²¹ 425 R⁷ G¹² W²¹ 426 R⁸ G¹² W²¹ 427 R¹⁰ G¹² W²¹ 428 R¹² G¹² W²¹ 429 R¹⁴ G¹² W²¹ 430 R¹⁵ G¹² W²¹ 431 R¹⁹ G¹² W²¹ 432 R²⁷ G¹² W²¹ 433 R²⁸ G¹² W²¹ 434 R³³ G¹² W²¹ 435 R³⁸ G¹² W²¹ 436 R³⁹ G¹² W²¹ 437 R⁴¹ G¹² W²¹ 438 R⁴⁶ G¹² W²¹ 439 R⁴⁷ G¹² W²¹ 440 R⁴⁹ G¹² W²¹ 441 R¹ G¹³ W²¹ 442 R² G¹³ W²¹ 443 R⁴ G¹³ W²¹ 444 R⁵ G¹³ W²¹ 445 R⁷ G¹³ W²¹ 446 R⁸ G¹³ W²¹ 447 R¹⁰ G¹³ W²¹ 448 R¹² G¹³ W²¹ 449 R¹⁴ G¹³ W²¹ 450 R¹⁵ G¹³ W²¹ 451 R¹⁹ G¹³ W²¹ 452 R²⁷ G¹³ W²¹ 453 R²⁸ G¹³ W²¹ 454 R³³ G¹³ W²¹ 455 R³⁸ G¹³ W²¹ 456 R³⁹ G¹³ W²¹ 457 R⁴¹ G¹³ W²¹ 458 R⁴⁶ G¹³ W²¹ 459 R⁴⁷ G¹³ W²¹ 460 R⁴⁹ G¹³ W²¹ 461 R¹ G¹⁶ W²¹ 462 R² G¹⁶ W²¹ 463 R⁴ G¹⁶ W²¹ 464 R⁵ G¹⁶ W²¹ 465 R⁷ G¹⁶ W²¹ 466 R⁸ G¹⁶ W²¹ 467 R¹⁰ G¹⁶ W²¹ 468 R¹² G¹⁶ W²¹ 469 R¹⁴ G¹⁶ W²¹ 470 R¹⁵ G¹⁶ W²¹ 471 R¹⁹ G¹⁶ W²¹ 472 R²⁷ G¹⁶ W²¹ 473 R²⁸ G¹⁶ W²¹ 474 R³³ G¹⁶ W²¹ 475 R³⁸ G¹⁶ W²¹ 476 R³⁹ G¹⁶ W²¹ 477 R⁴¹ G¹⁶ W²¹ 478 R⁴⁶ G¹⁶ W²¹ 479 R⁴⁷ G¹⁶ W²¹ 480 R⁴⁹ G¹⁶ W²¹ 481 R¹ G¹⁷ W²¹ 482 R² G¹⁷ W²¹ 483 R⁴ G¹⁷ W²¹ 484 R⁵ G¹⁷ W²¹ 485 R⁷ G¹⁷ W²¹ 486 R⁸ G¹⁷ W²¹ 487 R¹⁰ G¹⁷ W²¹ 488 R¹² G¹⁷ W²¹ 489 R¹⁴ G¹⁷ W²¹ 490 R¹⁵ G¹⁷ W²¹ 491 R¹⁹ G¹⁷ W²¹ 492 R²⁷ G¹⁷ W²¹ 493 R²⁸ G¹⁷ W²¹ 494 R³³ G¹⁷ W²¹ 495 R³⁸ G¹⁷ W²¹ 496 R³⁹ G¹⁷ W²¹ 497 R⁴¹ G¹⁷ W²¹ 498 R⁴⁶ G¹⁷ W²¹ 499 R⁴⁷ G¹⁷ W²¹ 500 R⁴⁹ G¹⁷ W²¹ 501 R¹ G¹⁸ W²¹ 502 R² G¹⁸ W²¹ 503 R⁴ G¹⁸ W²¹ 504 R⁵ G¹⁸ W²¹ 505 R⁷ G¹⁸ W²¹ 506 R⁸ G¹⁸ W²¹ 507 R¹⁰ G¹⁸ W²¹ 508 R¹² G¹⁸ W²¹ 509 R¹⁴ G¹⁸ W²¹ 510 R¹⁵ G¹⁸ W²¹ 511 R¹⁹ G¹⁸ W²¹ 512 R²⁷ G¹⁸ W²¹ 513 R²⁸ G¹⁸ W²¹ 514 R³³ G¹⁸ W²¹ 515 R³⁸ G¹⁸ W²¹ 516 R³⁹ G¹⁸ W²¹ 517 R⁴¹ G¹⁸ W²¹ 518 R⁴⁶ G¹⁸ W²¹ 519 R⁴⁷ G¹⁸ W²¹ 520 R⁴⁹ G¹⁸ W²¹ 521 R¹ G²¹ W²¹ 522 R² G²¹ W²¹ 523 R⁴ G²¹ W²¹ 524 R⁵ G²¹ W²¹ 525 R⁷ G²¹ W²¹ 526 R⁸ G²¹ W²¹ 527 R¹⁰ G²¹ W²¹ 528 R¹² G²¹ W²¹ 529 R¹⁴ G²¹ W²¹ 530 R¹⁵ G²¹ W²¹ 531 R¹⁹ G²¹ W²¹ 532 R²⁷ G²¹ W²¹ 533 R²⁸ G²¹ W²¹ 534 R³³ G²¹ W²¹ 535 R³⁸ G²¹ W²¹ 536 R³⁹ G²¹ W²¹ 537 R⁴¹ G²¹ W²¹ 538 R⁴⁶ G²¹ W²¹ 539 R⁴⁷ G²¹ W²¹ 540 R⁴⁹ G²¹ W²¹ 541 R¹ G²² W²¹ 542 R² G²² W²¹ 543 R⁴ G²² W²¹ 544 R⁵ G²² W²¹ 545 R⁷ G²² W²¹ 546 R⁸ G²² W²¹ 547 R¹⁰ G²² W²¹ 548 R¹² G²² W²¹ 549 R¹⁴ G²² W²¹ 550 R¹⁵ G²² W²¹ 551 R¹⁹ G²² W²¹ 552 R²⁷ G²² W²¹ 553 R²⁸ G²² W²¹ 554 R³³ G²² W²¹ 555 R³⁸ G²² W²¹ 556 R³⁹ G²² W²¹ 557 R⁴¹ G²² W²¹ 558 R⁴⁶ G²² W²¹ 559 R⁴⁷ G²² W²¹ 560 R⁴⁹ G²² W²¹ 561 R¹ G²³ W²¹ 562 R² G²³ W²¹ 563 R⁴ G²³ W²¹ 564 R⁵ G²³ W²¹ 565 R⁷ G²³ W²¹ 566 R⁸ G²³ W²¹ 567 R¹⁰ G²³ W²¹ 568 R¹² G²³ W²¹ 569 R¹⁴ G²³ W²¹ 570 R¹⁵ G²³ W²¹ 571 R¹⁹ G²³ W²¹ 572 R²⁷ G²³ W²¹ 573 R²⁸ G²³ W²¹ 574 R³³ G²³ W²¹ 575 R³⁸ G²³ W²¹ 576 R³⁹ G²³ W²¹ 577 R⁴¹ G²³ W²¹ 578 R⁴⁶ G²³ W²¹ 579 R⁴⁷ G²³ W²¹ 580 R⁴⁹ G²³ W²¹ 581 R¹ G²⁴ W²¹ 582 R² G²⁴ W²¹ 583 R⁴ G²⁴ W²¹ 584 R⁵ G²⁴ W²¹ 585 R⁷ G²⁴ W²¹ 586 R⁸ G²⁴ W²¹ 587 R¹⁰ G²⁴ W²¹ 588 R¹² G²⁴ W²¹ 589 R¹⁴ G²⁴ W²¹ 590 R¹⁵ G²⁴ W²¹ 591 R¹⁹ G²⁴ W²¹ 592 R²⁷ G²⁴ W²¹ 593 R²⁸ G²⁴ W²¹ 594 R³³ G²⁴ W²¹ 595 R³⁸ G²⁴ W²¹ 596 R³⁹ G²⁴ W²¹ 597 R⁴¹ G²⁴ W²¹ 598 R⁴⁶ G²⁴ W²¹ 599 R⁴⁷ G²⁴ W²¹ 600 R⁴⁹ G²⁴ W²¹ 601 R¹ G¹¹ W²⁸ 602 R² G¹¹ W²⁸ 603 R⁴ G¹¹ W²⁸ 604 R⁵ G¹¹ W²⁸ 605 R⁷ G¹¹ W²⁸ 606 R⁸ G¹¹ W²⁸ 607 R¹⁰ G¹¹ W²⁸ 608 R¹² G¹¹ W²⁸ 609 R¹⁴ G¹¹ W²⁸ 610 R¹⁵ G¹¹ W²⁸ 611 R¹⁹ G¹¹ W²⁸ 612 R²⁷ G¹¹ W²⁸ 613 R²⁸ G¹¹ W²⁸ 614 R³³ G¹¹ W²⁸ 615 R³⁸ G¹¹ W²⁸ 616 R³⁹ G¹¹ W²⁸ 617 R⁴¹ G¹¹ W²⁸ 618 R⁴⁶ G¹¹ W²⁸ 619 R⁴⁷ G¹¹ W²⁸ 620 R⁴⁹ G¹¹ W²⁸ 621 R¹ G¹² W²⁸ 622 R² G¹² W²⁸ 623 R⁴ G¹² W²⁸ 624 R⁵ G¹² W²⁸ 625 R⁷ G¹² W²⁸ 626 R⁸ G¹² W²⁸ 627 R¹⁰ G¹² W²⁸ 628 R¹² G¹² W²⁸ 629 R¹⁴ G¹² W²⁸ 630 R¹⁵ G¹² W²⁸ 631 R¹⁹ G¹² W²⁸ 632 R²⁷ G¹² W²⁸ 633 R²⁸ G¹² W²⁸ 634 R³³ G¹² W²⁸ 635 R³⁸ G¹² W²⁸ 636 R³⁹ G¹² W²⁸ 637 R⁴¹ G¹² W²⁸ 638 R⁴⁶ G¹² W²⁸ 639 R⁴⁷ G¹² W²⁸ 640 R⁴⁹ G¹² W²⁸ 641 R¹ G¹³ W²⁸ 642 R² G¹³ W²⁸ 643 R⁴ G¹³ W²⁸ 644 R⁵ G¹³ W²⁸ 645 R⁷ G¹³ W²⁸ 646 R⁸ G¹³ W²⁸ 647 R¹⁰ G¹³ W²⁸ 648 R¹² G¹³ W²⁸ 649 R¹⁴ G¹³ W²⁸ 650 R¹⁵ G¹³ W²⁸ 651 R¹⁹ G¹³ W²⁸ 652 R²⁷ G¹³ W²⁸ 653 R²⁸ G¹³ W²⁸ 654 R³³ G¹³ W²⁸ 655 R³⁸ G¹³ W²⁸ 656 R³⁹ G¹³ W²⁸ 657 R⁴¹ G¹³ W²⁸ 658 R⁴⁶ G¹³ W²⁸ 659 R⁴⁷ G¹³ W²⁸ 660 R⁴⁹ G¹³ W²⁸ 661 R¹ G¹⁴ W²⁸ 662 R² G¹⁴ W²⁸ 663 R⁴ G¹⁴ W²⁸ 664 R⁵ G¹⁴ W²⁸ 665 R⁷ G¹⁴ W²⁸ 666 R⁸ G¹⁴ W²⁸ 667 R¹⁰ G¹⁴ W²⁸ 668 R¹² G¹⁴ W²⁸ 669 R¹⁴ G¹⁴ W²⁸ 670 R¹⁵ G¹⁴ W²⁸ 671 R¹⁹ G¹⁴ W²⁸ 672 R²⁷ G¹⁴ W²⁸ 673 R²⁸ G¹⁴ W²⁸ 674 R³³ G¹⁴ W²⁸ 675 R³⁸ G¹⁴ W²⁸ 676 R³⁹ G¹⁴ W²⁸ 677 R⁴¹ G¹⁴ W²⁸ 678 R⁴⁶ G¹⁴ W²⁸ 679 R⁴⁷ G¹⁴ W²⁸ 680 R⁴⁹ G¹⁴ W²⁸ 681 R¹ G¹⁵ W²⁸ 682 R² G¹⁵ W²⁸ 683 R⁴ G¹⁵ W²⁸ 684 R⁵ G¹⁵ W²⁸ 685 R⁷ G¹⁵ W²⁸ 686 R⁸ G¹⁵ W²⁸ 687 R¹⁰ G¹⁵ W²⁸ 688 R¹² G¹⁵ W²⁸ 689 R¹⁴ G¹⁵ W²⁸ 690 R¹⁵ G¹⁵ W²⁸ 691 R¹⁹ G¹⁵ W²⁸ 692 R²⁷ G¹⁵ W²⁸ 693 R²⁸ G¹⁵ W²⁸ 694 R³³ G¹⁵ W²⁸ 695 R³⁸ G¹⁵ W²⁸ 696 R³⁹ G¹⁵ W²⁸ 697 R⁴¹ G¹⁵ W²⁸ 698 R⁴⁶ G¹⁵ W²⁸ 699 R⁴⁷ G¹⁵ W²⁸ 700 R⁴⁹ G¹⁵ W²⁸ 701 R¹ G¹⁶ W²⁸ 702 R² G¹⁶ W²⁸ 703 R⁴ G¹⁶ W²⁸ 704 R⁵ G¹⁶ W²⁸ 705 R⁷ G¹⁶ W²⁸ 706 R⁸ G¹⁶ W²⁸ 707 R¹⁰ G¹⁶ W²⁸ 708 R¹² G¹⁶ W²⁸ 709 R¹⁴ G¹⁶ W²⁸ 710 R¹⁵ G¹⁶ W²⁸ 711 R¹⁹ G¹⁶ W²⁸ 712 R²⁷ G¹⁶ W²⁸ 713 R²⁸ G¹⁶ W²⁸ 714 R³³ G¹⁶ W²⁸ 715 R³⁸ G¹⁶ W²⁸ 716 R³⁹ G¹⁶ W²⁸ 717 R⁴¹ G¹⁶ W²⁸ 718 R⁴⁶ G¹⁶ W²⁸ 719 R⁴⁷ G¹⁶ W²⁸ 720 R⁴⁹ G¹⁶ W²⁸ 721 R¹ G¹⁷ W²⁸ 722 R² G¹⁷ W²⁸ 723 R⁴ G¹⁷ W²⁸ 724 R⁵ G¹⁷ W²⁸ 725 R⁷ G¹⁷ W²⁸ 726 R⁸ G¹⁷ W²⁸ 727 R¹⁰ G¹⁷ W²⁸ 728 R¹² G¹⁷ W²⁸ 729 R¹⁴ G¹⁷ W²⁸ 730 R¹⁵ G¹⁷ W²⁸ 731 R¹⁹ G¹⁷ W²⁸ 732 R²⁷ G¹⁷ W²⁸ 733 R²⁸ G¹⁷ W²⁸ 734 R³³ G¹⁷ W²⁸ 735 R³⁸ G¹⁷ W²⁸ 736 R³⁹ G¹⁷ W²⁸ 737 R⁴¹ G¹⁷ W²⁸ 738 R⁴⁶ G¹⁷ W²⁸ 739 R⁴⁷ G¹⁷ W²⁸ 740 R⁴⁹ G¹⁷ W²⁸ 741 R¹ G¹⁸ W²⁸ 742 R² G¹⁸ W²⁸ 743 R⁴ G¹⁸ W²⁸ 744 R⁵ G¹⁸ W²⁸ 745 R⁷ G¹⁸ W²⁸ 746 R⁸ G¹⁸ W²⁸ 747 R¹⁰ G¹⁸ W²⁸ 748 R¹² G¹⁸ W²⁸ 749 R¹⁴ G¹⁸ W²⁸ 750 R¹⁵ G¹⁸ W²⁸ 751 R¹⁹ G¹⁸ W²⁸ 752 R²⁷ G¹⁸ W²⁸ 753 R²⁸ G¹⁸ W²⁸ 754 R³³ G¹⁸ W²⁸ 755 R³⁸ G¹⁸ W²⁸ 756 R³⁹ G¹⁸ W²⁸ 757 R⁴¹ G¹⁸ W²⁸ 758 R⁴⁶ G¹⁸ W²⁸ 759 R⁴⁷ G¹⁸ W²⁸ 760 R⁴⁹ G¹⁸ W²⁸ 761 R¹ G¹⁹ W²⁸ 762 R² G¹⁹ W²⁸ 763 R⁴ G¹⁹ W²⁸ 764 R⁵ G¹⁹ W²⁸ 765 R⁷ G¹⁹ W²⁸ 766 R⁸ G¹⁹ W²⁸ 767 R¹⁰ G¹⁹ W²⁸ 768 R¹² G¹⁹ W²⁸ 769 R¹⁴ G¹⁹ W²⁸ 770 R¹⁵ G¹⁹ W²⁸ 771 R¹⁹ G¹⁹ W²⁸ 772 R²⁷ G¹⁹ W²⁸ 773 R²⁸ G¹⁹ W²⁸ 774 R³³ G¹⁹ W²⁸ 775 R³⁸ G¹⁹ W²⁸ 776 R³⁹ G¹⁹ W²⁸ 777 R⁴¹ G¹⁹ W²⁸ 778 R⁴⁶ G¹⁹ W²⁸ 779 R⁴⁷ G¹⁹ W²⁸ 780 R⁴⁹ G¹⁹ W²⁸ 781 R¹ G²⁰ W²⁸ 782 R² G²⁰ W²⁸ 783 R⁴ G²⁰ W²⁸ 784 R⁵ G²⁰ W²⁸ 785 R⁷ G²⁰ W²⁸ 786 R⁸ G²⁰ W²⁸ 787 R¹⁰ G²⁰ W²⁸ 788 R¹² G²⁰ W²⁸ 789 R¹⁴ G²⁰ W²⁸ 790 R¹⁵ G²⁰ W²⁸ 791 R¹⁹ G²⁰ W²⁸ 792 R²⁷ G²⁰ W²⁸ 793 R²⁸ G²⁰ W²⁸ 794 R³³ G²⁰ W²⁸ 795 R³⁸ G²⁰ W²⁸ 796 R³⁹ G²⁰ W²⁸ 797 R⁴¹ G²⁰ W²⁸ 798 R⁴⁶ G²⁰ W²⁸ 799 R⁴⁷ G²⁰ W²⁸ 800 R⁴⁹ G²⁰ W²⁸ 801 R¹ G¹¹ W³⁶ 802 R² G¹¹ W³⁶ 803 R⁴ G¹¹ W³⁶ 804 R⁵ G¹¹ W³⁶ 805 R⁷ G¹¹ W³⁶ 806 R⁸ G¹¹ W³⁶ 807 R¹⁰ G¹¹ W³⁶ 808 R¹² G¹¹ W³⁶ 809 R¹⁴ G¹¹ W³⁶ 810 R¹⁵ G¹¹ W³⁶ 811 R¹⁹ G¹¹ W³⁶ 812 R²⁷ G¹¹ W³⁶ 813 R²⁸ G¹¹ W³⁶ 814 R³³ G¹¹ W³⁶ 815 R³⁸ G¹¹ W³⁶ 816 R³⁹ G¹¹ W³⁶ 817 R⁴¹ G¹¹ W³⁶ 818 R⁴⁶ G¹¹ W³⁶ 819 R⁴⁷ G¹¹ W³⁶ 820 R⁴⁹ G¹¹ W³⁶ 821 R¹ G¹² W³⁶ 822 R² G¹² W³⁶ 823 R⁴ G¹² W³⁶ 824 R⁵ G¹² W³⁶ 825 R⁷ G¹² W³⁶ 826 R⁸ G¹² W³⁶ 827 R¹⁰ G¹² W³⁶ 828 R¹² G¹² W³⁶ 829 R¹⁴ G¹² W³⁶ 830 R¹⁵ G¹² W³⁶ 831 R¹⁹ G¹² W³⁶ 832 R²⁷ G¹² W³⁶ 833 R²⁸ G¹² W³⁶ 834 R³³ G¹² W³⁶ 835 R³⁸ G¹² W³⁶ 836 R³⁹ G¹² W³⁶ 837 R⁴¹ G¹² W³⁶ 838 R⁴⁶ G¹² W³⁶ 839 R⁴⁷ G¹² W³⁶ 840 R⁴⁹ G¹² W³⁶ 841 R¹ G¹³ W³⁶ 842 R² G¹³ W³⁶ 843 R⁴ G¹³ W³⁶ 844 R⁵ G¹³ W³⁶ 845 R⁷ G¹³ W³⁶ 846 R⁸ G¹³ W³⁶ 847 R¹⁰ G¹³ W³⁶ 848 R¹² G¹³ W³⁶ 849 R¹⁴ G¹³ W³⁶ 850 R¹⁵ G¹³ W³⁶ 851 R¹⁹ G¹³ W³⁶ 852 R²⁷ G¹³ W³⁶ 853 R²⁸ G¹³ W³⁶ 854 R³³ G¹³ W³⁶ 855 R³⁸ G¹³ W³⁶ 856 R³⁹ G¹³ W³⁶ 857 R⁴¹ G¹³ W³⁶ 858 R⁴⁶ G¹³ W³⁶ 859 R⁴⁷ G¹³ W³⁶ 860 R⁴⁹ G¹³ W³⁶ 861 R¹ G¹⁴ W³⁶ 862 R² G¹⁴ W³⁶ 863 R⁴ G¹⁴ W³⁶ 864 R⁵ G¹⁴ W³⁶ 865 R⁷ G¹⁴ W³⁶ 866 R⁸ G¹⁴ W³⁶ 867 R¹⁰ G¹⁴ W³⁶ 868 R¹² G¹⁴ W³⁶ 869 R¹⁴ G¹⁴ W³⁶ 870 R¹⁵ G¹⁴ W³⁶ 871 R¹⁹ G¹⁴ W³⁶ 872 R²⁷ G¹⁴ W³⁶ 873 R²⁸ G¹⁴ W³⁶ 874 R³³ G¹⁴ W³⁶ 875 R³⁸ G¹⁴ W³⁶ 876 R³⁹ G¹⁴ W³⁶ 877 R⁴¹ G¹⁴ W³⁶ 878 R⁴⁶ G¹⁴ W³⁶ 879 R⁴⁷ G¹⁴ W³⁶ 880 R⁴⁹ G¹⁴ W³⁶ 881 R¹ G¹⁵ W³⁶ 882 R² G¹⁵ W³⁶ 883 R⁴ G¹⁵ W³⁶ 884 R⁵ G¹⁵ W³⁶ 885 R⁷ G¹⁵ W³⁶ 886 R⁸ G¹⁵ W³⁶ 887 R¹⁰ G¹⁵ W³⁶ 888 R¹² G¹⁵ W³⁶ 889 R¹⁴ G¹⁵ W³⁶ 890 R¹⁵ G¹⁵ W³⁶ 891 R¹⁹ G¹⁵ W³⁶ 892 R²⁷ G¹⁵ W³⁶ 893 R²⁸ G¹⁵ W³⁶ 894 R³³ G¹⁵ W³⁶ 895 R³⁸ G¹⁵ W³⁶ 896 R³⁹ G¹⁵ W³⁶ 897 R⁴¹ G¹⁵ W³⁶ 898 R⁴⁶ G¹⁵ W³⁶ 899 R⁴⁷ G¹⁵ W³⁶ 900 R⁴⁹ G¹⁵ W³⁶ 901 R¹ G¹⁶ W³⁶ 902 R² G¹⁶ W³⁶ 903 R⁴ G¹⁶ W³⁶ 904 R⁵ G¹⁶ W³⁶ 905 R⁷ G¹⁶ W³⁶ 906 R⁸ G¹⁶ W³⁶ 907 R¹⁰ G¹⁶ W³⁶ 908 R¹² G¹⁶ W³⁶ 909 R¹⁴ G¹⁶ W³⁶ 910 R¹⁵ G¹⁶ W³⁶ 911 R¹⁹ G¹⁶ W³⁶ 912 R²⁷ G¹⁶ W³⁶ 913 R²⁸ G¹⁶ W³⁶ 914 R³³ G¹⁶ W³⁶ 915 R³⁸ G¹⁶ W³⁶ 916 R³⁹ G¹⁶ W³⁶ 917 R⁴¹ G¹⁶ W³⁶ 918 R⁴⁶ G¹⁶ W³⁶ 919 R⁴⁷ G¹⁶ W³⁶ 920 R⁴⁹ G¹⁶ W³⁶ 921 R¹ G¹⁷ W³⁶ 922 R² G¹⁷ W³⁶ 923 R⁴ G¹⁷ W³⁶ 924 R⁵ G¹⁷ W³⁶ 925 R⁷ G¹⁷ W³⁶ 926 R⁸ G¹⁷ W³⁶ 927 R¹⁰ G¹⁷ W³⁶ 928 R¹² G¹⁷ W³⁶ 929 R¹⁴ G¹⁷ W³⁶ 930 R¹⁵ G¹⁷ W³⁶ 931 R¹⁹ G¹⁷ W³⁶ 932 R²⁷ G¹⁷ W³⁶ 933 R²⁸ G¹⁷ W³⁶ 934 R³³ G¹⁷ W³⁶ 935 R³⁸ G¹⁷ W³⁶ 936 R³⁹ G¹⁷ W³⁶ 937 R⁴¹ G¹⁷ W³⁶ 938 R⁴⁶ G¹⁷ W³⁶ 939 R⁴⁷ G¹⁷ W³⁶ 940 R⁴⁹ G¹⁷ W³⁶ 941 R¹ G¹⁸ W³⁶ 942 R² G¹⁸ W³⁶ 943 R⁴ G¹⁸ W³⁶ 944 R⁵ G¹⁸ W³⁶ 945 R⁷ G¹⁸ W³⁶ 946 R⁸ G¹⁸ W³⁶ 947 R¹⁰ G¹⁸ W³⁶ 948 R¹² G¹⁸ W³⁶ 949 R¹⁴ G¹⁸ W³⁶ 950 R¹⁵ G¹⁸ W³⁶ 951 R¹⁹ G¹⁸ W³⁶ 952 R²⁷ G¹⁸ W³⁶ 953 R²⁸ G¹⁸ W³⁶ 954 R³³ G¹⁸ W³⁶ 955 R³⁸ G¹⁸ W³⁶ 956 R³⁹ G¹⁸ W³⁶ 957 R⁴¹ G¹⁸ W³⁶ 958 R⁴⁶ G¹⁸ W³⁶ 959 R⁴⁷ G¹⁸ W³⁶ 960 R⁴⁹ G¹⁸ W³⁶ 961 R¹ G¹⁹ W³⁶ 962 R² G¹⁹ W³⁶ 963 R⁴ G¹⁹ W³⁶ 964 R⁵ G¹⁹ W³⁶ 965 R⁷ G¹⁹ W³⁶ 966 R⁸ G¹⁹ W³⁶ 967 R¹⁰ G¹⁹ W³⁶ 968 R¹² G¹⁹ W³⁶ 969 R¹⁴ G¹⁹ W³⁶ 970 R¹⁵ G¹⁹ W³⁶ 971 R¹⁹ G¹⁹ W³⁶ 972 R²⁷ G¹⁹ W³⁶ 973 R²⁸ G¹⁹ W³⁶ 974 R³³ G¹⁹ W³⁶ 975 R³⁸ G¹⁹ W³⁶ 976 R³⁹ G¹⁹ W³⁶ 977 R⁴¹ G¹⁹ W³⁶ 978 R⁴⁶ G¹⁹ W³⁶ 979 R⁴⁷ G¹⁹ W³⁶ 980 R⁴⁹ G¹⁹ W³⁶ 981 R¹ G²⁰ W³⁶ 982 R² G²⁰ W³⁶ 983 R⁴ G²⁰ W³⁶ 984 R⁵ G²⁰ W³⁶ 985 R⁷ G²⁰ W³⁶ 986 R⁸ G²⁰ W³⁶ 987 R¹⁰ G²⁰ W³⁶ 988 R¹² G²⁰ W³⁶ 989 R¹⁴ G²⁰ W³⁶ 990 R¹⁵ G²⁰ W³⁶ 991 R¹⁹ G²⁰ W³⁶ 992 R²⁷ G²⁰ W³⁶ 993 R²⁸ G²⁰ W³⁶ 994 R³³ G²⁰ W³⁶ 995 R³⁸ G²⁰ W³⁶ 996 R³⁹ G²⁰ W³⁶ 997 R⁴¹ G²⁰ W³⁶ 998 R⁴⁶ G²⁰ W³⁶ 999 R⁴⁷ G²⁰ W³⁶ 1000 R⁴⁹ G²⁰ W³⁶ 1001 R¹ G¹¹ W³⁷ 1002 R² G¹¹ W³⁷ 1003 R⁴ G¹¹ W³⁷ 1004 R⁵ G¹¹ W³⁷ 1005 R⁷ G¹¹ W³⁷ 1006 R⁸ G¹¹ W³⁷ 1007 R¹⁰ G¹¹ W³⁷ 1008 R¹² G¹¹ W³⁷ 1009 R¹⁴ G¹¹ W³⁷ 1010 R¹⁵ G¹¹ W³⁷ 1011 R¹⁹ G¹¹ W³⁷ 1012 R²⁷ G¹¹ W³⁷ 1013 R²⁸ G¹¹ W³⁷ 1014 R³³ G¹¹ W³⁷ 1015 R³⁸ G¹¹ W³⁷ 1016 R³⁹ G¹¹ W³⁷ 1017 R⁴¹ G¹¹ W³⁷ 1018 R⁴⁶ G¹¹ W³⁷ 1019 R⁴⁷ G¹¹ W³⁷ 1020 R⁴⁹ G¹¹ W³⁷ 1021 R¹ G¹² W³⁷ 1022 R² G¹² W³⁷ 1023 R⁴ G¹² W³⁷ 1024 R⁵ G¹² W³⁷ 1025 R⁷ G¹² W³⁷ 1026 R⁸ G¹² W³⁷ 1027 R¹⁰ G¹² W³⁷ 1028 R¹² G¹² W³⁷ 1029 R¹⁴ G¹² W³⁷ 1030 R¹⁵ G¹² W³⁷ 1031 R¹⁹ G¹² W³⁷ 1032 R²⁷ G¹² W³⁷ 1033 R²⁸ G¹² W³⁷ 1034 R³³ G¹² W³⁷ 1035 R³⁸ G¹² W³⁷ 1036 R³⁹ G¹² W³⁷ 1037 R⁴¹ G¹² W³⁷ 1038 R⁴⁶ G¹² W³⁷ 1039 R⁴⁷ G¹² W³⁷ 1040 R⁴⁹ G¹² W³⁷ 1041 R¹ G¹³ W³⁷ 1042 R² G¹³ W³⁷ 1043 R⁴ G¹³ W³⁷ 1044 R⁵ G¹³ W³⁷ 1045 R⁷ G¹³ W³⁷ 1046 R⁸ G¹³ W³⁷ 1047 R¹⁰ G¹³ W³⁷ 1048 R¹² G¹³ W³⁷ 1049 R¹⁴ G¹³ W³⁷ 1050 R¹⁵ G¹³ W³⁷ 1051 R¹⁹ G¹³ W³⁷ 1052 R²⁷ G¹³ W³⁷ 1053 R²⁸ G¹³ W³⁷ 1054 R³³ G¹³ W³⁷ 1055 R³⁸ G¹³ W³⁷ 1056 R³⁹ G¹³ W³⁷ 1057 R⁴¹ G¹³ W³⁷ 1058 R⁴⁶ G¹³ W³⁷ 1059 R⁴⁷ G¹³ W³⁷ 1060 R⁴⁹ G¹³ W³⁷ 1061 R¹ G¹⁴ W³⁷ 1062 R² G¹⁴ W³⁷ 1063 R⁴ G¹⁴ W³⁷ 1064 R⁵ G¹⁴ W³⁷ 1065 R⁷ G¹⁴ W³⁷ 1066 R⁸ G¹⁴ W³⁷ 1067 R¹⁰ G¹⁴ W³⁷ 1068 R¹² G¹⁴ W³⁷ 1069 R¹⁴ G¹⁴ W³⁷ 1070 R¹⁵ G¹⁴ W³⁷ 1071 R¹⁹ G¹⁴ W³⁷ 1072 R²⁷ G¹⁴ W³⁷ 1073 R²⁸ G¹⁴ W³⁷ 1074 R³³ G¹⁴ W³⁷ 1075 R³⁸ G¹⁴ W³⁷ 1076 R³⁹ G¹⁴ W³⁷ 1077 R⁴¹ G¹⁴ W³⁷ 1078 R⁴⁶ G¹⁴ W³⁷ 1079 R⁴⁷ G¹⁴ W³⁷ 1080 R⁴⁹ G¹⁴ W³⁷ 1081 R¹ G¹⁵ W³⁷ 1082 R² G¹⁵ W³⁷ 1083 R⁴ G¹⁵ W³⁷ 1084 R⁵ G¹⁵ W³⁷ 1085 R⁷ G¹⁵ W³⁷ 1086 R⁸ G¹⁵ W³⁷ 1087 R¹⁰ G¹⁵ W³⁷ 1088 R¹² G¹⁵ W³⁷ 1089 R¹⁴ G¹⁵ W³⁷ 1090 R¹⁵ G¹⁵ W³⁷ 1091 R¹⁹ G¹⁵ W³⁷ 1092 R²⁷ G¹⁵ W³⁷ 1093 R²⁸ G¹⁵ W³⁷ 1094 R³³ G¹⁵ W³⁷ 1095 R³⁸ G¹⁵ W³⁷ 1096 R³⁹ G¹⁵ W³⁷ 1097 R⁴¹ G¹⁵ W³⁷ 1098 R⁴⁶ G¹⁵ W³⁷ 1099 R⁴⁷ G¹⁵ W³⁷ 1100 R⁴⁹ G¹⁵ W³⁷ 1101 R¹ G¹⁶ W³⁷ 1102 R² G¹⁶ W³⁷ 1103 R⁴ G¹⁶ W³⁷ 1104 R⁵ G¹⁶ W³⁷ 1105 R⁷ G¹⁶ W³⁷ 1106 R⁸ G¹⁶ W³⁷ 1107 R¹⁰ G¹⁶ W³⁷ 1108 R¹² G¹⁶ W³⁷ 1109 R¹⁴ G¹⁶ W³⁷ 1110 R¹⁵ G¹⁶ W³⁷ 1111 R¹⁹ G¹⁶ W³⁷ 1112 R²⁷ G¹⁶ W³⁷ 1113 R²⁸ G¹⁶ W³⁷ 1114 R³³ G¹⁶ W³⁷ 1115 R³⁸ G¹⁶ W³⁷ 1116 R³⁹ G¹⁶ W³⁷ 1117 R⁴¹ G¹⁶ W³⁷ 1118 R⁴⁶ G¹⁶ W³⁷ 1119 R⁴⁷ G¹⁶ W³⁷ 1120 R⁴⁹ G¹⁶ W³⁷ 1121 R¹ G¹⁷ W³⁷ 1122 R² G¹⁷ W³⁷ 1123 R⁴ G¹⁷ W³⁷ 1124 R⁵ G¹⁷ W³⁷ 1125 R⁷ G¹⁷ W³⁷ 1126 R⁸ G¹⁷ W³⁷ 1127 R¹⁰ G¹⁷ W³⁷ 1128 R¹² G¹⁷ W³⁷ 1129 R¹⁴ G¹⁷ W³⁷ 1130 R¹⁵ G¹⁷ W³⁷ 1131 R¹⁹ G¹⁷ W³⁷ 1132 R²⁷ G¹⁷ W³⁷ 1133 R²⁸ G¹⁷ W³⁷ 1134 R³³ G¹⁷ W³⁷ 1135 R³⁸ G¹⁷ W³⁷ 1136 R³⁹ G¹⁷ W³⁷ 1137 R⁴¹ G¹⁷ W³⁷ 1138 R⁴⁶ G¹⁷ W³⁷ 1139 R⁴⁷ G¹⁷ W³⁷ 1140 R⁴⁹ G¹⁷ W³⁷ 1141 R¹ G¹⁸ W³⁷ 1142 R² G¹⁸ W³⁷ 1143 R⁴ G¹⁸ W³⁷ 1144 R⁵ G¹⁸ W³⁷ 1145 R⁷ G¹⁸ W³⁷ 1146 R⁸ G¹⁸ W³⁷ 1147 R¹⁰ G¹⁸ W³⁷ 1148 R¹² G¹⁸ W³⁷ 1149 R¹⁴ G¹⁸ W³⁷ 1150 R¹⁵ G¹⁸ W³⁷ 1151 R¹⁹ G¹⁸ W³⁷ 1152 R²⁷ G¹⁸ W³⁷ 1153 R²⁸ G¹⁸ W³⁷ 1154 R³³ G¹⁸ W³⁷ 1155 R³⁸ G¹⁸ W³⁷ 1156 R³⁹ G¹⁸ W³⁷ 1157 R⁴¹ G¹⁸ W³⁷ 1158 R⁴⁶ G¹⁸ W³⁷ 1159 R⁴⁷ G¹⁸ W³⁷ 1160 R⁴⁹ G¹⁸ W³⁷ 1161 R¹ G¹⁹ W³⁷ 1162 R² G¹⁹ W³⁷ 1163 R⁴ G¹⁹ W³⁷ 1164 R⁵ G¹⁹ W³⁷ 1165 R⁷ G¹⁹ W³⁷ 1166 R⁸ G¹⁹ W³⁷ 1167 R¹⁰ G¹⁹ W³⁷ 1168 R¹² G¹⁹ W³⁷ 1169 R¹⁴ G¹⁹ W³⁷ 1170 R¹⁵ G¹⁹ W³⁷ 1171 R¹⁹ G¹⁹ W³⁷ 1172 R²⁷ G¹⁹ W³⁷ 1173 R²⁸ G¹⁹ W³⁷ 1174 R³³ G¹⁹ W³⁷ 1175 R³⁸ G¹⁹ W³⁷ 1176 R³⁹ G¹⁹ W³⁷ 1177 R⁴¹ G¹⁹ W³⁷ 1178 R⁴⁶ G¹⁹ W³⁷ 1179 R⁴⁷ G¹⁹ W³⁷ 1180 R⁴⁹ G¹⁹ W³⁷ 1181 R¹ G²⁰ W³⁷ 1182 R² G²⁰ W³⁷ 1183 R⁴ G²⁰ W³⁷ 1184 R⁵ G²⁰ W³⁷ 1185 R⁷ G²⁰ W³⁷ 1186 R⁸ G²⁰ W³⁷ 1187 R¹⁰ G²⁰ W³⁷ 1188 R¹² G²⁰ W³⁷ 1189 R¹⁴ G²⁰ W³⁷ 1190 R¹⁵ G²⁰ W³⁷ 1191 R¹⁹ G²⁰ W³⁷ 1192 R²⁷ G²⁰ W³⁷ 1193 R²⁸ G²⁰ W³⁷ 1194 R³³ G²⁰ W³⁷ 1195 R³⁸ G²⁰ W³⁷ 1196 R³⁹ G²⁰ W³⁷ 1197 R⁴¹ G²⁰ W³⁷ 1198 R⁴⁶ G²⁰ W³⁷ 1199 R⁴⁷ G²⁰ W³⁷ 1200 R⁴⁹ G²⁰ W³⁷ 1201 R¹ G²⁹ W⁴² 1202 R² G²⁹ W⁴² 1203 R⁴ G²⁹ W⁴² 1204 R⁵ G²⁹ W⁴² 1205 R⁷ G²⁹ W⁴² 1206 R⁸ G²⁹ W⁴² 1207 R¹⁰ G²⁹ W⁴² 1208 R¹² G²⁹ W⁴² 1209 R¹⁴ G²⁹ W⁴² 1210 R¹⁵ G²⁹ W⁴² 1211 R¹⁹ G²⁹ W⁴² 1212 R²⁷ G²⁹ W⁴² 1213 R²⁸ G²⁹ W⁴² 1214 R³³ G²⁹ W⁴² 1215 R³⁸ G²⁹ W⁴² 1216 R³⁹ G²⁹ W⁴² 1217 R⁴¹ G²⁹ W⁴² 1218 R⁴⁶ G²⁹ W⁴² 1219 R⁴⁷ G²⁹ W⁴² 1220 R⁴⁹ G²⁹ W⁴² 1221 R¹ G³⁰ W⁴² 1222 R² G³⁰ W⁴² 1223 R⁴ G³⁰ W⁴² 1224 R⁵ G³⁰ W⁴² 1225 R⁷ G³⁰ W⁴² 1226 R⁸ G³⁰ W⁴² 1227 R¹⁰ G³⁰ W⁴² 1228 R¹² G³⁰ W⁴² 1229 R¹⁴ G³⁰ W⁴² 1230 R¹⁵ G³⁰ W⁴² 1231 R¹⁹ G³⁰ W⁴² 1232 R²⁷ G³⁰ W⁴² 1233 R²⁸ G³⁰ W⁴² 1234 R³³ G³⁰ W⁴² 1235 R³⁸ G³⁰ W⁴² 1236 R³⁹ G³⁰ W⁴² 1237 R⁴¹ G³⁰ W⁴² 1238 R⁴⁶ G³⁰ W⁴² 1239 R⁴⁷ G³⁰ W⁴² 1240 R⁴⁹ G³⁰ W⁴² 1241 R¹ G³¹ W⁴² 1242 R² G³¹ W⁴² 1243 R⁴ G³¹ W⁴² 1244 R⁵ G³¹ W⁴² 1245 R⁷ G³¹ W⁴² 1246 R⁸ G³¹ W⁴² 1247 R¹⁰ G³¹ W⁴² 1248 R¹² G³¹ W⁴² 1249 R¹⁴ G³¹ W⁴² 1250 R¹⁵ G³¹ W⁴² 1251 R¹⁹ G³¹ W⁴² 1252 R²⁷ G³¹ W⁴² 1253 R²⁸ G³¹ W⁴² 1254 R³³ G³¹ W⁴² 1255 R³⁸ G³¹ W⁴² 1256 R³⁹ G³¹ W⁴² 1257 R⁴¹ G³¹ W⁴² 1258 R⁴⁶ G³¹ W⁴² 1259 R⁴⁷ G³¹ W⁴² 1260 R⁴⁹ G³¹ W⁴² 1261 R¹ G³² W⁴² 1262 R² G³² W⁴² 1263 R⁴ G³² W⁴² 1264 R⁵ G³² W⁴² 1265 R⁷ G³² W⁴² 1266 R⁸ G³² W⁴² 1267 R¹⁰ G³² W⁴² 1268 R¹² G³² W⁴² 1269 R¹⁴ G³² W⁴² 1270 R¹⁵ G³² W⁴² 1271 R¹⁹ G³² W⁴² 1272 R²⁷ G³² W⁴² 1273 R²⁸ G³² W⁴² 1274 R³³ G³² W⁴² 1275 R³⁸ G³² W⁴² 1276 R³⁹ G³² W⁴² 1277 R⁴¹ G³² W⁴² 1278 R⁴⁶ G³² W⁴² 1279 R⁴⁷ G³² W⁴² 1280 R⁴⁹ G³² W⁴² 1281 R¹ G³³ W⁴² 1282 R² G³³ W⁴² 1283 R⁴ G³³ W⁴² 1284 R⁵ G³³ W⁴² 1285 R⁷ G³³ W⁴² 1286 R⁸ G³³ W⁴² 1287 R¹⁰ G³³ W⁴² 1288 R¹² G³³ W⁴² 1289 R¹⁴ G³³ W⁴² 1290 R¹⁵ G³³ W⁴² 1291 R¹⁹ G³³ W⁴² 1292 R²⁷ G³³ W⁴² 1293 R²⁸ G³³ W⁴² 1294 R³³ G³³ W⁴² 1295 R³⁸ G³³ W⁴² 1296 R³⁹ G³³ W⁴² 1297 R⁴¹ G³³ W⁴² 1298 R⁴⁶ G³³ W⁴² 1299 R⁴⁷ G³³ W⁴² 1300 R⁴⁹ G³³ W⁴² 1301 R¹ G³⁴ W⁴² 1302 R² G³⁴ W⁴² 1303 R⁴ G³⁴ W⁴² 1304 R⁵ G³⁴ W⁴² 1305 R⁷ G³⁴ W⁴² 1306 R⁸ G³⁴ W⁴² 1307 R¹⁰ G³⁴ W⁴² 1308 R¹² G³⁴ W⁴² 1309 R¹⁴ G³⁴ W⁴² 1310 R¹⁵ G³⁴ W⁴² 1311 R¹⁹ G³⁴ W⁴² 1312 R²⁷ G³⁴ W⁴² 1313 R²⁸ G³⁴ W⁴² 1314 R³³ G³⁴ W⁴² 1315 R³⁸ G³⁴ W⁴² 1316 R³⁹ G³⁴ W⁴² 1317 R⁴¹ G³⁴ W⁴² 1318 R⁴⁶ G³⁴ W⁴² 1319 R⁴⁷ G³⁴ W⁴² 1320 R⁴⁹ G³⁴ W⁴² 1321 R¹ G³⁵ W⁴² 1322 R² G³⁵ W⁴² 1323 R⁴ G³⁵ W⁴² 1324 R⁵ G³⁵ W⁴² 1325 R⁷ G³⁵ W⁴² 1326 R⁸ G³⁵ W⁴² 1327 R¹⁰ G³⁵ W⁴² 1328 R¹² G³⁵ W⁴² 1329 R¹⁴ G³⁵ W⁴² 1330 R¹⁵ G³⁵ W⁴² 1331 R¹⁹ G³⁵ W⁴² 1332 R²⁷ G³⁵ W⁴² 1333 R²⁸ G³⁵ W⁴² 1334 R³³ G³⁵ W⁴² 1335 R³⁸ G³⁵ W⁴² 1336 R³⁹ G³⁵ W⁴² 1337 R⁴¹ G³⁵ W⁴² 1338 R⁴⁶ G³⁵ W⁴² 1339 R⁴⁷ G³⁵ W⁴² 1340 R⁴⁹ G³⁵ W⁴² 1341 R¹ G³⁶ W⁴² 1342 R² G³⁶ W⁴² 1343 R⁴ G³⁶ W⁴² 1344 R⁵ G³⁶ W⁴² 1345 R⁷ G³⁶ W⁴² 1346 R⁸ G³⁶ W⁴² 1347 R¹⁰ G³⁶ W⁴² 1348 R¹² G³⁶ W⁴² 1349 R¹⁴ G³⁶ W⁴² 1350 R¹⁵ G³⁶ W⁴² 1351 R¹⁹ G³⁶ W⁴² 1352 R²⁷ G³⁶ W⁴² 1353 R²⁸ G³⁶ W⁴² 1354 R³³ G³⁶ W⁴² 1355 R³⁸ G³⁶ W⁴² 1356 R³⁹ G³⁶ W⁴² 1357 R⁴¹ G³⁶ W⁴² 1358 R⁴⁶ G³⁶ W⁴² 1359 R⁴⁷ G³⁶ W⁴² 1360 R⁴⁹ G³⁶ W⁴² 1361 R¹ G³⁷ W⁴² 1362 R² G³⁷ W⁴² 1363 R⁴ G³⁷ W⁴² 1364 R⁵ G³⁷ W⁴² 1365 R⁷ G³⁷ W⁴² 1366 R⁸ G³⁷ W⁴² 1367 R¹⁰ G³⁷ W⁴² 1368 R¹² G³⁷ W⁴² 1369 R¹⁴ G³⁷ W⁴² 1370 R¹⁵ G³⁷ W⁴² 1371 R¹⁹ G³⁷ W⁴² 1372 R²⁷ G³⁷ W⁴² 1373 R²⁸ G³⁷ W⁴² 1374 R³³ G³⁷ W⁴² 1375 R³⁸ G³⁷ W⁴² 1376 R³⁹ G³⁷ W⁴² 1377 R⁴¹ G³⁷ W⁴² 1378 R⁴⁶ G³⁷ W⁴² 1379 R⁴⁷ G³⁷ W⁴² 1380 R⁴⁹ G³⁷ W⁴² 1381 R¹ G³⁹ W⁴² 1382 R² G³⁹ W⁴² 1383 R⁴ G³⁹ W⁴² 1384 R⁵ G³⁹ W⁴² 1385 R⁷ G³⁹ W⁴² 1386 R⁸ G³⁹ W⁴² 1387 R¹⁰ G³⁹ W⁴² 1388 R¹² G³⁹ W⁴² 1389 R¹⁴ G³⁹ W⁴² 1390 R¹⁵ G³⁹ W⁴² 1391 R¹⁹ G³⁹ W⁴² 1392 R²⁷ G³⁹ W⁴² 1393 R²⁸ G³⁹ W⁴² 1394 R³³ G³⁹ W⁴² 1395 R³⁸ G³⁹ W⁴² 1396 R³⁹ G³⁹ W⁴² 1397 R⁴¹ G³⁹ W⁴² 1398 R⁴⁶ G³⁹ W⁴² 1399 R⁴⁷ G³⁹ W⁴² 1400 R⁴⁹ G³⁹ W⁴² 1401 R¹ G¹⁴ W¹ 1402 R² G¹⁴ W¹ 1403 R⁴ G¹⁴ W¹ 1404 R⁵ G¹⁴ W¹ 1405 R⁷ G¹⁴ W¹ 1406 R⁸ G¹⁴ W¹ 1407 R¹⁰ G¹⁴ W¹ 1408 R¹² G¹⁴ W¹ 1409 R¹⁴ G¹⁴ W¹ 1410 R¹⁵ G¹⁴ W¹ 1411 R¹⁹ G¹⁴ W¹ 1412 R²⁷ G¹⁴ W¹ 1413 R²⁸ G¹⁴ W¹ 1414 R³³ G¹⁴ W¹ 1415 R³⁸ G¹⁴ W¹ 1416 R³⁹ G¹⁴ W¹ 1417 R⁴¹ G¹⁴ W¹ 1418 R⁴⁶ G¹⁴ W¹ 1419 R⁴⁷ G¹⁴ W¹ 1420 R⁴⁹ G¹⁴ W¹ 1421 R¹ G¹⁵ W¹ 1422 R² G¹⁵ W¹ 1423 R⁴ G¹⁵ W¹ 1424 R⁵ G¹⁵ W¹ 1425 R⁷ G¹⁵ W¹ 1426 R⁸ G¹⁵ W¹ 1427 R¹⁰ G¹⁵ W¹ 1428 R¹² G¹⁵ W¹ 1429 R¹⁴ G¹⁵ W¹ 1430 R¹⁵ G¹⁵ W¹ 1431 R¹⁹ G¹⁵ W¹ 1432 R²⁷ G¹⁵ W¹ 1433 R²⁸ G¹⁵ W¹ 1434 R³³ G¹⁵ W¹ 1435 R³⁸ G¹⁵ W¹ 1436 R³⁹ G¹⁵ W¹ 1437 R⁴¹ G¹⁵ W¹ 1438 R⁴⁶ G¹⁵ W¹ 1439 R⁴⁷ G¹⁵ W¹ 1440 R⁴⁹ G¹⁵ W¹ 1441 R¹ G¹⁹ W¹ 1442 R² G¹⁹ W¹ 1443 R⁴ G¹⁹ W¹ 1444 R⁵ G¹⁹ W¹ 1445 R⁷ G¹⁹ W¹ 1446 R⁸ G¹⁹ W¹ 1447 R¹⁰ G¹⁹ W¹ 1448 R¹² G¹⁹ W¹ 1449 R¹⁴ G¹⁹ W¹ 1450 R¹⁵ G¹⁹ W¹ 1451 R¹⁹ G¹⁹ W¹ 1452 R²⁷ G¹⁹ W¹ 1453 R²⁸ G¹⁹ W¹ 1454 R³³ G¹⁹ W¹ 1455 R³⁸ G¹⁹ W¹ 1456 R³⁹ G¹⁹ W¹ 1457 R⁴¹ G¹⁹ W¹ 1458 R⁴⁶ G¹⁹ W¹ 1459 R⁴⁷ G¹⁹ W¹ 1460 R⁴⁹ G¹⁹ W¹ 1461 R¹ G²⁰ W¹ 1462 R² G²⁰ W¹ 1463 R⁴ G²⁰ W¹ 1464 R⁵ G²⁰ W¹ 1465 R⁷ G²⁰ W¹ 1466 R⁸ G²⁰ W¹ 1467 R¹⁰ G²⁰ W¹ 1468 R¹² G²⁰ W¹ 1469 R¹⁴ G²⁰ W¹ 1470 R¹⁵ G²⁰ W¹ 1471 R¹⁹ G²⁰ W¹ 1472 R²⁷ G²⁰ W¹ 1473 R²⁸ G²⁰ W¹ 1474 R³³ G²⁰ W¹ 1475 R³⁸ G²⁰ W¹ 1476 R³⁹ G²⁰ W¹ 1477 R⁴¹ G²⁰ W¹ 1478 R⁴⁶ G²⁰ W¹ 1479 R⁴⁷ G²⁰ W¹ 1480 R⁴⁹ G²⁰ W¹ 1481 R¹ G¹⁴ W¹¹ 1482 R² G¹⁴ W¹¹ 1483 R⁴ G¹⁴ W¹¹ 1484 R⁵ G¹⁴ W¹¹ 1485 R⁷ G¹⁴ W¹¹ 1486 R⁸ G¹⁴ W¹¹ 1487 R¹⁰ G¹⁴ W¹¹ 1488 R¹² G¹⁴ W¹¹ 1489 R¹⁴ G¹⁴ W¹¹ 1490 R¹⁵ G¹⁴ W¹¹ 1491 R¹⁹ G¹⁴ W¹¹ 1492 R²⁷ G¹⁴ W¹¹ 1493 R²⁸ G¹⁴ W¹¹ 1494 R³³ G¹⁴ W¹¹ 1495 R³⁸ G¹⁴ W¹¹ 1496 R³⁹ G¹⁴ W¹¹ 1497 R⁴¹ G¹⁴ W¹¹ 1498 R⁴⁶ G¹⁴ W¹¹ 1499 R⁴⁷ G¹⁴ W¹¹ 1500 R⁴⁹ G¹⁴ W¹¹ 1501 R¹ G¹⁵ W¹¹ 1502 R² G¹⁵ W¹¹ 1503 R⁴ G¹⁵ W¹¹ 1504 R⁵ G¹⁵ W¹¹ 1505 R⁷ G¹⁵ W¹¹ 1506 R⁸ G¹⁵ W¹¹ 1507 R¹⁰ G¹⁵ W¹¹ 1508 R¹² G¹⁵ W¹¹ 1509 R¹⁴ G¹⁵ W¹¹ 1510 R¹⁵ G¹⁵ W¹¹ 1511 R¹⁹ G¹⁵ W¹¹ 1512 R²⁷ G¹⁵ W¹¹ 1513 R²⁸ G¹⁵ W¹¹ 1514 R³³ G¹⁵ W¹¹ 1515 R³⁸ G¹⁵ W¹¹ 1516 R³⁹ G¹⁵ W¹¹ 1517 R⁴¹ G¹⁵ W¹¹ 1518 R⁴⁶ G¹⁵ W¹¹ 1519 R⁴⁷ G¹⁵ W¹¹ 1520 R⁴⁹ G¹⁵ W¹¹ 1521 R¹ G¹⁹ W¹¹ 1522 R² G¹⁹ W¹¹ 1523 R⁴ G¹⁹ W¹¹ 1524 R⁵ G¹⁹ W¹¹ 1525 R⁷ G¹⁹ W¹¹ 1526 R⁸ G¹⁹ W¹¹ 1527 R¹⁰ G¹⁹ W¹¹ 1528 R¹² G¹⁹ W¹¹ 1529 R¹⁴ G¹⁹ W¹¹ 1530 R¹⁵ G¹⁹ W¹¹ 1531 R¹⁹ G¹⁹ W¹¹ 1532 R²⁷ G¹⁹ W¹¹ 1533 R²⁸ G¹⁹ W¹¹ 1534 R³³ G¹⁹ W¹¹ 1535 R³⁸ G¹⁹ W¹¹ 1536 R³⁹ G¹⁹ W¹¹ 1537 R⁴¹ G¹⁹ W¹¹ 1538 R⁴⁶ G¹⁹ W¹¹ 1539 R⁴⁷ G¹⁹ W¹¹ 1540 R⁴⁹ G¹⁹ W¹¹ 1541 R¹ G²⁰ W¹¹ 1542 R² G²⁰ W¹¹ 1543 R⁴ G²⁰ W¹¹ 1544 R⁵ G²⁰ W¹¹ 1545 R⁷ G²⁰ W¹¹ 1546 R⁸ G²⁰ W¹¹ 1547 R¹⁰ G²⁰ W¹¹ 1548 R¹² G²⁰ W¹¹ 1549 R¹⁴ G²⁰ W¹¹ 1550 R¹⁵ G²⁰ W¹¹ 1551 R¹⁹ G²⁰ W¹¹ 1552 R²⁷ G²⁰ W¹¹ 1553 R²⁸ G²⁰ W¹¹ 1554 R³³ G²⁰ W¹¹ 1555 R³⁸ G²⁰ W¹¹ 1556 R³⁹ G²⁰ W¹¹ 1557 R⁴¹ G²⁰ W¹¹ 1558 R⁴⁶ G²⁰ W¹¹ 1559 R⁴⁷ G²⁰ W¹¹ 1560 R⁴⁹ G²⁰ W¹¹ 1561 R¹ G² W¹ 1562 R² G² W¹ 1563 R³ G² W¹ 1564 R⁴ G² W¹ 1565 R⁵ G² W¹ 1566 R⁶ G² W¹ 1567 R⁷ G² W¹ 1568 R⁸ G² W¹ 1569 R⁹ G² W¹ 1570 R¹⁰ G² W¹ 1571 R¹¹ G² W¹ 1572 R¹² G² W¹ 1573 R¹³ G² W¹ 1574 R¹⁴ G² W¹ 1575 R¹⁵ G² W¹ 1576 R¹⁶ G² W¹ 1577 R¹⁷ G² W¹ 1578 R¹⁸ G² W¹ 1579 R¹⁹ G² W¹ 1580 R²⁰ G² W¹ 1581 R²¹ G² W¹ 1582 R²² G² W¹ 1583 R²³ G² W¹ 1584 R²⁴ G² W¹ 1585 R²⁵ G² W¹ 1586 R²⁶ G² W¹ 1587 R²⁷ G² W¹ 1588 R²⁸ G² W¹ 1589 R²⁹ G² W¹ 1590 R³⁰ G² W¹ 1591 R³¹ G² W¹ 1592 R³² G² W¹ 1593 R³³ G² W¹ 1594 R³⁴ G² W¹ 1595 R³⁵ G² W¹ 1596 R³⁶ G² W¹ 1597 R³⁷ G² W¹ 1598 R³⁸ G² W¹ 1599 R³⁹ G² W¹ 1600 R⁴⁰ G² W¹ 1601 R⁴¹ G² W¹ 1602 R⁴² G² W¹ 1603 R⁴³ G² W¹ 1604 R⁴⁴ G² W¹ 1605 R⁴⁵ G² W¹ 1606 R⁴⁶ G² W¹ 1607 R⁴⁷ G² W¹ 1608 R⁴⁸ G² W¹ 1609 R⁴⁹ G² W¹ 1610 R⁵⁰ G² W¹ 1611 R¹ G⁴ W¹ 1612 R² G⁴ W¹ 1613 R³ G⁴ W¹ 1614 R⁴ G⁴ W¹ 1615 R⁵ G⁴ W¹ 1616 R⁶ G⁴ W¹ 1617 R⁷ G⁴ W¹ 1618 R⁸ G⁴ W¹ 1619 R⁹ G⁴ W¹ 1620 R¹⁰ G⁴ W¹ 1621 R¹¹ G⁴ W¹ 1622 R¹² G⁴ W¹ 1623 R¹³ G⁴ W¹ 1624 R¹⁴ G⁴ W¹ 1625 R¹⁵ G⁴ W¹ 1626 R¹⁶ G⁴ W¹ 1627 R¹⁷ G⁴ W¹ 1628 R¹⁸ G⁴ W¹ 1629 R¹⁹ G⁴ W¹ 1630 R²⁰ G⁴ W¹ 1631 R²¹ G⁴ W¹ 1632 R²² G⁴ W¹ 1633 R²³ G⁴ W¹ 1634 R²⁴ G⁴ W¹ 1635 R²⁵ G⁴ W¹ 1636 R²⁶ G⁴ W¹ 1637 R²⁷ G⁴ W¹ 1638 R²⁸ G⁴ W¹ 1639 R²⁹ G⁴ W¹ 1640 R³⁰ G⁴ W¹ 1641 R³¹ G⁴ W¹ 1642 R³² G⁴ W¹ 1643 R³³ G⁴ W¹ 1644 R³⁴ G⁴ W¹ 1645 R³⁵ G⁴ W¹ 1646 R³⁶ G⁴ W¹ 1647 R³⁷ G⁴ W¹ 1648 R³⁸ G⁴ W¹ 1649 R³⁹ G⁴ W¹ 1650 R⁴⁰ G⁴ W¹ 1651 R⁴¹ G⁴ W¹ 1652 R⁴² G⁴ W¹ 1653 R⁴³ G⁴ W¹ 1654 R⁴⁴ G⁴ W¹ 1655 R⁴⁵ G⁴ W¹ 1656 R⁴⁶ G⁴ W¹ 1657 R⁴⁷ G⁴ W¹ 1658 R⁴⁸ G⁴ W¹ 1659 R⁴⁹ G⁴ W¹ 1660 R⁵⁰ G⁴ W¹ 1661 R¹ G² W¹¹ 1662 R² G² W¹¹ 1663 R³ G² W¹¹ 1664 R⁴ G² W¹¹ 1665 R⁵ G² W¹¹ 1666 R⁶ G² W¹¹ 1667 R⁷ G² W¹¹ 1668 R⁸ G² W¹¹ 1669 R⁹ G² W¹¹ 1670 R¹⁰ G² W¹¹ 1671 R¹¹ G² W¹¹ 1672 R¹² G² W¹¹ 1673 R¹³ G² W¹¹ 1674 R¹⁴ G² W¹¹ 1675 R¹⁵ G² W¹¹ 1676 R¹⁶ G² W¹¹ 1677 R¹⁷ G² W¹¹ 1678 R¹⁸ G² W¹¹ 1679 R¹⁹ G² W¹¹ 1680 R²⁰ G² W¹¹ 1681 R²¹ G² W¹¹ 1682 R²² G² W¹¹ 1683 R²³ G² W¹¹ 1684 R²⁴ G² W¹¹ 1685 R²⁵ G² W¹¹ 1686 R²⁶ G² W¹¹ 1687 R²⁷ G² W¹¹ 1688 R²⁸ G² W¹¹ 1689 R²⁹ G² W¹¹ 1690 R³⁰ G² W¹¹ 1691 R³¹ G² W¹¹ 1692 R³² G² W¹¹ 1693 R³³ G² W¹¹ 1694 R³⁴ G² W¹¹ 1695 R³⁵ G² W¹¹ 1696 R³⁶ G² W¹¹ 1697 R³⁷ G² W¹¹ 1698 R³⁸ G² W¹¹ 1699 R³⁹ G² W¹¹ 1700 R⁴⁰ G² W¹¹ 1701 R⁴¹ G² W¹¹ 1702 R⁴² G² W¹¹ 1703 R⁴³ G² W¹¹ 1704 R⁴⁴ G² W¹¹ 1705 R⁴⁵ G² W¹¹ 1706 R⁴⁶ G² W¹¹ 1707 R⁴⁷ G² W¹¹ 1708 R⁴⁸ G² W¹¹ 1709 R⁴⁹ G² W¹¹ 1710 R⁵⁰ G² W¹¹ 1711 R¹ G⁴ W¹¹ 1712 R² G⁴ W¹¹ 1713 R³ G⁴ W¹¹ 1714 R⁴ G⁴ W¹¹ 1715 R⁵ G⁴ W¹¹ 1716 R⁶ G⁴ W¹¹ 1717 R⁷ G⁴ W¹¹ 1718 R⁸ G⁴ W¹¹ 1719 R⁹ G⁴ W¹¹ 1720 R¹⁰ G⁴ W¹¹ 1721 R¹¹ G⁴ W¹¹ 1722 R¹² G⁴ W¹¹ 1723 R¹³ G⁴ W¹¹ 1724 R¹⁴ G⁴ W¹¹ 1725 R¹⁵ G⁴ W¹¹ 1726 R¹⁶ G⁴ W¹¹ 1727 R¹⁷ G⁴ W¹¹ 1728 R¹⁸ G⁴ W¹¹ 1729 R¹⁹ G⁴ W¹¹ 1730 R²⁰ G⁴ W¹¹ 1731 R²¹ G⁴ W¹¹ 1732 R²² G⁴ W¹¹ 1733 R²³ G⁴ W¹¹ 1734 R²⁴ G⁴ W¹¹ 1735 R²⁵ G⁴ W¹¹ 1736 R²⁶ G⁴ W¹¹ 1737 R²⁷ G⁴ W¹¹ 1738 R²⁸ G⁴ W¹¹ 1739 R²⁹ G⁴ W¹¹ 1740 R³⁰ G⁴ W¹¹ 1741 R³¹ G⁴ W¹¹ 1742 R³² G⁴ W¹¹ 1743 R³³ G⁴ W¹¹ 1744 R³⁴ G⁴ W¹¹ 1745 R³⁵ G⁴ W¹¹ 1746 R³⁶ G⁴ W¹¹ 1747 R³⁷ G⁴ W¹¹ 1748 R³⁸ G⁴ W¹¹ 1749 R³⁹ G⁴ W¹¹ 1750 R⁴⁰ G⁴ W¹¹ 1751 R⁴¹ G⁴ W¹¹ 1752 R⁴² G⁴ W¹¹ 1753 R⁴³ G⁴ W¹¹ 1754 R⁴⁴ G⁴ W¹¹ 1755 R⁴⁵ G⁴ W¹¹ 1756 R⁴⁶ G⁴ W¹¹ 1757 R⁴⁷ G⁴ W¹¹ 1758 R⁴⁸ G⁴ W¹¹ 1759 R⁴⁹ G⁴ W¹¹ 1760 R⁵⁰ G⁴ W¹¹ 1761 R¹ G² W²¹ 1762 R² G² W²¹ 1763 R³ G² W²¹ 1764 R⁴ G² W²¹ 1765 R⁵ G² W²¹ 1766 R⁶ G² W²¹ 1767 R⁷ G² W²¹ 1768 R⁸ G² W²¹ 1769 R⁹ G² W²¹ 1770 R¹⁰ G² W²¹ 1771 R¹¹ G² W²¹ 1772 R¹² G² W²¹ 1773 R¹³ G² W²¹ 1774 R¹⁴ G² W²¹ 1775 R¹⁵ G² W²¹ 1776 R¹⁶ G² W²¹ 1777 R¹⁷ G² W²¹ 1778 R¹⁸ G² W²¹ 1779 R¹⁹ G² W²¹ 1780 R²⁰ G² W²¹ 1781 R²¹ G² W²¹ 1782 R²² G² W²¹ 1783 R²³ G² W²¹ 1784 R²⁴ G² W²¹ 1785 R²⁵ G² W²¹ 1786 R²⁶ G² W²¹ 1787 R²⁷ G² W²¹ 1788 R²⁸ G² W²¹ 1789 R²⁹ G² W²¹ 1790 R³⁰ G² W²¹ 1791 R³¹ G² W²¹ 1792 R³² G² W²¹ 1793 R³³ G² W²¹ 1794 R³⁴ G² W²¹ 1795 R³⁵ G² W²¹ 1796 R³⁶ G² W²¹ 1797 R³⁷ G² W²¹ 1798 R³⁸ G² W²¹ 1799 R³⁹ G² W²¹ 1800 R⁴⁰ G² W²¹ 1801 R⁴¹ G² W²¹ 1802 R⁴² G² W²¹ 1803 R⁴³ G² W²¹ 1804 R⁴⁴ G² W²¹ 1805 R⁴⁵ G² W²¹ 1806 R⁴⁶ G² W²¹ 1807 R⁴⁷ G² W²¹ 1808 R⁴⁸ G² W²¹ 1809 R⁴⁹ G² W²¹ 1810 R⁵⁰ G² W²¹ 1811 R¹ G⁴ W²¹ 1812 R² G⁴ W²¹ 1813 R³ G⁴ W²¹ 1814 R⁴ G⁴ W²¹ 1815 R⁵ G⁴ W²¹ 1816 R⁶ G⁴ W²¹ 1817 R⁷ G⁴ W²¹ 1818 R⁸ G⁴ W²¹ 1819 R⁹ G⁴ W²¹ 1820 R¹⁰ G⁴ W²¹ 1821 R¹¹ G⁴ W²¹ 1822 R¹² G⁴ W²¹ 1823 R¹³ G⁴ W²¹ 1824 R¹⁴ G⁴ W²¹ 1825 R¹⁵ G⁴ W²¹ 1826 R¹⁶ G⁴ W²¹ 1827 R¹⁷ G⁴ W²¹ 1828 R¹⁸ G⁴ W²¹ 1829 R¹⁹ G⁴ W²¹ 1830 R²⁰ G⁴ W²¹ 1831 R²¹ G⁴ W²¹ 1832 R²² G⁴ W²¹ 1833 R²³ G⁴ W²¹ 1834 R²⁴ G⁴ W²¹ 1835 R²⁵ G⁴ W²¹ 1836 R²⁶ G⁴ W²¹ 1837 R²⁷ G⁴ W²¹ 1838 R²⁸ G⁴ W²¹ 1839 R²⁹ G⁴ W²¹ 1840 R³⁰ G⁴ W²¹ 1841 R³¹ G⁴ W²¹ 1842 R³² G⁴ W²¹ 1843 R³³ G⁴ W²¹ 1844 R³⁴ G⁴ W²¹ 1845 R³⁵ G⁴ W²¹ 1846 R³⁶ G⁴ W²¹ 1847 R³⁷ G⁴ W²¹ 1848 R³⁸ G⁴ W²¹ 1849 R³⁹ G⁴ W²¹ 1850 R⁴⁰ G⁴ W²¹ 1851 R⁴¹ G⁴ W²¹ 1852 R⁴² G⁴ W²¹ 1853 R⁴³ G⁴ W²¹ 1854 R⁴⁴ G⁴ W²¹ 1855 R⁴⁵ G⁴ W²¹ 1856 R⁴⁶ G⁴ W²¹ 1857 R⁴⁷ G⁴ W²¹ 1858 R⁴⁸ G⁴ W²¹ 1859 R⁴⁹ G⁴ W²¹ 1860 R⁵⁰ G⁴ W²¹ 1861 R¹ G² W²⁸ 1862 R² G² W²⁸ 1863 R³ G² W²⁸ 1864 R⁴ G² W²⁸ 1865 R⁵ G² W²⁸ 1866 R⁶ G² W²⁸ 1867 R⁷ G² W²⁸ 1868 R⁸ G² W²⁸ 1869 R⁹ G² W²⁸ 1870 R¹⁰ G² W²⁸ 1871 R¹¹ G² W²⁸ 1872 R¹² G² W²⁸ 1873 R¹³ G² W²⁸ 1874 R¹⁴ G² W²⁸ 1875 R¹⁵ G² W²⁸ 1876 R¹⁶ G² W²⁸ 1877 R¹⁷ G² W²⁸ 1878 R¹⁸ G² W²⁸ 1879 R¹⁹ G² W²⁸ 1880 R²⁰ G² W²⁸ 1881 R²¹ G² W²⁸ 1882 R²² G² W²⁸ 1883 R²³ G² W²⁸ 1884 R²⁴ G² W²⁸ 1885 R²⁵ G² W²⁸ 1886 R²⁶ G² W²⁸ 1887 R²⁷ G² W²⁸ 1888 R²⁸ G² W²⁸ 1889 R²⁹ G² W²⁸ 1890 R³⁰ G² W²⁸ 1891 R³¹ G² W²⁸ 1892 R³² G² W²⁸ 1893 R³³ G² W²⁸ 1894 R³⁴ G² W²⁸ 1895 R³⁵ G² W²⁸ 1896 R³⁶ G² W²⁸ 1897 R³⁷ G² W²⁸ 1898 R³⁸ G² W²⁸ 1899 R³⁹ G² W²⁸ 1900 R⁴⁰ G² W²⁸ 1901 R⁴¹ G² W²⁸ 1902 R⁴² G² W²⁸ 1903 R⁴³ G² W²⁸ 1904 R⁴⁴ G² W²⁸ 1905 R⁴⁵ G² W²⁸ 1906 R⁴⁶ G² W²⁸ 1907 R⁴⁷ G² W²⁸ 1908 R⁴⁸ G² W²⁸ 1909 R⁴⁹ G² W²⁸ 1910 R⁵⁰ G² W²⁸ 1911 R¹ G⁴ W²⁸ 1912 R² G⁴ W²⁸ 1913 R³ G⁴ W²⁸ 1914 R⁴ G⁴ W²⁸ 1915 R⁵ G⁴ W²⁸ 1916 R⁶ G⁴ W²⁸ 1917 R⁷ G⁴ W²⁸ 1918 R⁸ G⁴ W²⁸ 1919 R⁹ G⁴ W²⁸ 1920 R¹⁰ G⁴ W²⁸ 1921 R¹¹ G⁴ W²⁸ 1922 R¹² G⁴ W²⁸ 1923 R¹³ G⁴ W²⁸ 1924 R¹⁴ G⁴ W²⁸ 1925 R¹⁵ G⁴ W²⁸ 1926 R¹⁶ G⁴ W²⁸ 1927 R¹⁷ G⁴ W²⁸ 1928 R¹⁸ G⁴ W²⁸ 1929 R¹⁹ G⁴ W²⁸ 1930 R²⁰ G⁴ W²⁸ 1931 R²¹ G⁴ W²⁸ 1932 R²² G⁴ W²⁸ 1933 R²³ G⁴ W²⁸ 1934 R²⁴ G⁴ W²⁸ 1935 R²⁵ G⁴ W²⁸ 1936 R²⁶ G⁴ W²⁸ 1937 R²⁷ G⁴ W²⁸ 1938 R²⁸ G⁴ W²⁸ 1939 R²⁹ G⁴ W²⁸ 1940 R³⁰ G⁴ W²⁸ 1941 R³¹ G⁴ W²⁸ 1942 R³² G⁴ W²⁸ 1943 R³³ G⁴ W²⁸ 1944 R³⁴ G⁴ W²⁸ 1945 R³⁵ G⁴ W²⁸ 1946 R³⁶ G⁴ W²⁸ 1947 R³⁷ G⁴ W²⁸ 1948 R³⁸ G⁴ W²⁸ 1949 R³⁹ G⁴ W²⁸ 1950 R⁴⁰ G⁴ W²⁸ 1951 R⁴¹ G⁴ W²⁸ 1952 R⁴² G⁴ W²⁸ 1953 R⁴³ G⁴ W²⁸ 1954 R⁴⁴ G⁴ W²⁸ 1955 R⁴⁵ G⁴ W²⁸ 1956 R⁴⁶ G⁴ W²⁸ 1957 R⁴⁷ G⁴ W²⁸ 1958 R⁴⁸ G⁴ W²⁸ 1959 R⁴⁹ G⁴ W²⁸ 1960 R⁵⁰ G⁴ W²⁸ 1961 R¹ G² W³⁶ 1962 R² G² W³⁶ 1963 R³ G² W³⁶ 1964 R⁴ G² W³⁶ 1965 R⁵ G² W³⁶ 1966 R⁶ G² W³⁶ 1967 R⁷ G² W³⁶ 1968 R⁸ G² W³⁶ 1969 R⁹ G² W³⁶ 1970 R¹⁰ G² W³⁶ 1971 R¹¹ G² W³⁶ 1972 R¹² G² W³⁶ 1973 R¹³ G² W³⁶ 1974 R¹⁴ G² W³⁶ 1975 R¹⁵ G² W³⁶ 1976 R¹⁶ G² W³⁶ 1977 R¹⁷ G² W³⁶ 1978 R¹⁸ G² W³⁶ 1979 R¹⁹ G² W³⁶ 1980 R²⁰ G² W³⁶ 1981 R²¹ G² W³⁶ 1982 R²² G² W³⁶ 1983 R²³ G² W³⁶ 1984 R²⁴ G² W³⁶ 1985 R²⁵ G² W³⁶ 1986 R²⁶ G² W³⁶ 1987 R²⁷ G² W³⁶ 1988 R²⁸ G² W³⁶ 1989 R²⁹ G² W³⁶ 1990 R³⁰ G² W³⁶ 1991 R³¹ G² W³⁶ 1992 R³² G² W³⁶ 1993 R³³ G² W³⁶ 1994 R³⁴ G² W³⁶ 1995 R³⁵ G² W³⁶ 1996 R³⁶ G² W³⁶ 1997 R³⁷ G² W³⁶ 1998 R³⁸ G² W³⁶ 1999 R³⁹ G² W³⁶ 2000 R⁴⁰ G² W³⁶ 2001 R⁴¹ G² W³⁶ 2002 R⁴² G² W³⁶ 2003 R⁴³ G² W³⁶ 2004 R⁴⁴ G² W³⁶ 2005 R⁴⁵ G² W³⁶ 2006 R⁴⁶ G² W³⁶ 2007 R⁴⁷ G² W³⁶ 2008 R⁴⁸ G² W³⁶ 2009 R⁴⁹ G² W³⁶ 2010 R⁵⁰ G² W³⁶ 2011 R¹ G⁴ W³⁶ 2012 R² G⁴ W³⁶ 2013 R³ G⁴ W³⁶ 2014 R⁴ G⁴ W³⁶ 2015 R⁵ G⁴ W³⁶ 2016 R⁶ G⁴ W³⁶ 2017 R⁷ G⁴ W³⁶ 2018 R⁸ G⁴ W³⁶ 2019 R⁹ G⁴ W³⁶ 2020 R¹⁰ G⁴ W³⁶ 2021 R¹¹ G⁴ W³⁶ 2022 R¹² G⁴ W³⁶ 2023 R¹³ G⁴ W³⁶ 2024 R¹⁴ G⁴ W³⁶ 2025 R¹⁵ G⁴ W³⁶ 2026 R¹⁶ G⁴ W³⁶ 2027 R¹⁷ G⁴ W³⁶ 2028 R¹⁸ G⁴ W³⁶ 2029 R¹⁹ G⁴ W³⁶ 2030 R²⁰ G⁴ W³⁶ 2031 R²¹ G⁴ W³⁶ 2032 R²² G⁴ W³⁶ 2033 R²³ G⁴ W³⁶ 2034 R²⁴ G⁴ W³⁶ 2035 R²⁵ G⁴ W³⁶ 2036 R²⁶ G⁴ W³⁶ 2037 R²⁷ G⁴ W³⁶ 2038 R²⁸ G⁴ W³⁶ 2039 R²⁹ G⁴ W³⁶ 2040 R³⁰ G⁴ W³⁶ 2041 R³¹ G⁴ W³⁶ 2042 R³² G⁴ W³⁶ 2043 R³³ G⁴ W³⁶ 2044 R³⁴ G⁴ W³⁶ 2045 R³⁵ G⁴ W³⁶ 2046 R³⁶ G⁴ W³⁶ 2047 R³⁷ G⁴ W³⁶ 2048 R³⁸ G⁴ W³⁶ 2049 R³⁹ G⁴ W³⁶ 2050 R⁴⁰ G⁴ W³⁶ 2051 R⁴¹ G⁴ W³⁶ 2052 R⁴² G⁴ W³⁶ 2053 R⁴³ G⁴ W³⁶ 2054 R⁴⁴ G⁴ W³⁶ 2055 R⁴⁵ G⁴ W³⁶ 2056 R⁴⁶ G⁴ W³⁶ 2057 R⁴⁷ G⁴ W³⁶ 2058 R⁴⁸ G⁴ W³⁶ 2059 R⁴⁹ G⁴ W³⁶ 2060 R⁵⁰ G⁴ W³⁶ 2061 R¹ G² W³⁷ 2062 R² G² W³⁷ 2063 R³ G² W³⁷ 2064 R⁴ G² W³⁷ 2065 R⁵ G² W³⁷ 2066 R⁶ G² W³⁷ 2067 R⁷ G² W³⁷ 2068 R⁸ G² W³⁷ 2069 R⁹ G² W³⁷ 2070 R¹⁰ G² W³⁷ 2071 R¹¹ G² W³⁷ 2072 R¹² G² W³⁷ 2073 R¹³ G² W³⁷ 2074 R¹⁴ G² W³⁷ 2075 R¹⁵ G² W³⁷ 2076 R¹⁶ G² W³⁷ 2077 R¹⁷ G² W³⁷ 2078 R¹⁸ G² W³⁷ 2079 R¹⁹ G² W³⁷ 2080 R²⁰ G² W³⁷ 2081 R²¹ G² W³⁷ 2082 R²² G² W³⁷ 2083 R²³ G² W³⁷ 2084 R²⁴ G² W³⁷ 2085 R²⁵ G² W³⁷ 2086 R²⁶ G² W³⁷ 2087 R²⁷ G² W³⁷ 2088 R²⁸ G² W³⁷ 2089 R²⁹ G² W³⁷ 2090 R³⁰ G² W³⁷ 2091 R³¹ G² W³⁷ 2092 R³² G² W³⁷ 2093 R³³ G² W³⁷ 2094 R³⁴ G² W³⁷ 2095 R³⁵ G² W³⁷ 2096 R³⁶ G² W³⁷ 2097 R³⁷ G² W³⁷ 2098 R³⁸ G² W³⁷ 2099 R³⁹ G² W³⁷ 2100 R⁴⁰ G² W³⁷ 2101 R⁴¹ G² W³⁷ 2102 R⁴² G² W³⁷ 2103 R⁴³ G² W³⁷ 2104 R⁴⁴ G² W³⁷ 2105 R⁴⁵ G² W³⁷ 2106 R⁴⁶ G² W³⁷ 2107 R⁴⁷ G² W³⁷ 2108 R⁴⁸ G² W³⁷ 2109 R⁴⁹ G² W³⁷ 2110 R⁵⁰ G² W³⁷ 2111 R¹ G⁴ W³⁷ 2112 R² G⁴ W³⁷ 2113 R³ G⁴ W³⁷ 2114 R⁴ G⁴ W³⁷ 2115 R⁵ G⁴ W³⁷ 2116 R⁶ G⁴ W³⁷ 2117 R⁷ G⁴ W³⁷ 2118 R⁸ G⁴ W³⁷ 2119 R⁹ G⁴ W³⁷ 2120 R¹⁰ G⁴ W³⁷ 2121 R¹¹ G⁴ W³⁷ 2122 R¹² G⁴ W³⁷ 2123 R¹³ G⁴ W³⁷ 2124 R¹⁴ G⁴ W³⁷ 2125 R¹⁵ G⁴ W³⁷ 2126 R¹⁶ G⁴ W³⁷ 2127 R¹⁷ G⁴ W³⁷ 2128 R¹⁸ G⁴ W³⁷ 2129 R¹⁹ G⁴ W³⁷ 2130 R²⁰ G⁴ W³⁷ 2131 R²¹ G⁴ W³⁷ 2132 R²² G⁴ W³⁷ 2133 R²³ G⁴ W³⁷ 2134 R²⁴ G⁴ W³⁷ 2135 R²⁵ G⁴ W³⁷ 2136 R²⁶ G⁴ W³⁷ 2137 R²⁷ G⁴ W³⁷ 2138 R²⁸ G⁴ W³⁷ 2139 R²⁹ G⁴ W³⁷ 2140 R³⁰ G⁴ W³⁷ 2141 R³¹ G⁴ W³⁷ 2142 R³² G⁴ W³⁷ 2143 R³³ G⁴ W³⁷ 2144 R³⁴ G⁴ W³⁷ 2145 R³⁵ G⁴ W³⁷ 2146 R³⁶ G⁴ W³⁷ 2147 R³⁷ G⁴ W³⁷ 2148 R³⁸ G⁴ W³⁷ 2149 R³⁹ G⁴ W³⁷ 2150 R⁴⁰ G⁴ W³⁷ 2151 R⁴¹ G⁴ W³⁷ 2152 R⁴² G⁴ W³⁷ 2153 R⁴³ G⁴ W³⁷ 2154 R⁴⁴ G⁴ W³⁷ 2155 R⁴⁵ G⁴ W³⁷ 2156 R⁴⁶ G⁴ W³⁷ 2157 R⁴⁷ G⁴ W³⁷ 2158 R⁴⁸ G⁴ W³⁷ 2159 R⁴⁹ G⁴ W³⁷ 2160 R⁵⁰ G⁴ W³⁷ 2161 R¹ G¹ W¹ 2162 R² G¹ W¹ 2163 R⁴ G¹ W¹ 2164 R⁵ G¹ W¹ 2165 R⁷ G¹ W¹ 2166 R⁸ G¹ W¹ 2167 R¹⁰ G¹ W¹ 2168 R¹² G¹ W¹ 2169 R¹⁴ G¹ W¹ 2170 R¹⁵ G¹ W¹ 2171 R¹⁹ G¹ W¹ 2172 R²⁷ G¹ W¹ 2173 R²⁸ G¹ W¹ 2174 R³³ G¹ W¹ 2175 R³⁸ G¹ W¹ 2176 R³⁹ G¹ W¹ 2177 R⁴¹ G¹ W¹ 2178 R⁴⁶ G¹ W¹ 2179 R⁴⁷ G¹ W¹ 2180 R⁴⁹ G¹ W¹ 2181 R¹ G³ W¹ 2182 R² G³ W¹ 2183 R⁴ G³ W¹ 2184 R⁵ G³ W¹ 2185 R⁷ G³ W¹ 2186 R⁸ G³ W¹ 2187 R¹⁰ G³ W¹ 2188 R¹² G³ W¹ 2189 R¹⁴ G³ W¹ 2190 R¹⁵ G³ W¹ 2191 R¹⁹ G³ W¹ 2192 R²⁷ G³ W¹ 2193 R²⁸ G³ W¹ 2194 R³³ G³ W¹ 2195 R³⁸ G³ W¹ 2196 R³⁹ G³ W¹ 2197 R⁴¹ G³ W¹ 2198 R⁴⁶ G³ W¹ 2199 R⁴⁷ G³ W¹ 2200 R⁴⁹ G³ W¹ 2201 R¹ G⁵ W¹ 2202 R² G⁵ W¹ 2203 R⁴ G⁵ W¹ 2204 R⁵ G⁵ W¹ 2205 R⁷ G⁵ W¹ 2206 R⁸ G⁵ W¹ 2207 R¹⁰ G⁵ W¹ 2208 R¹² G⁵ W¹ 2209 R¹⁴ G⁵ W¹ 2210 R¹⁵ G⁵ W¹ 2211 R¹⁹ G⁵ W¹ 2212 R²⁷ G⁵ W¹ 2213 R²⁸ G⁵ W¹ 2214 R³³ G⁵ W¹ 2215 R³⁸ G⁵ W¹ 2216 R³⁹ G⁵ W¹ 2217 R⁴¹ G⁵ W¹ 2218 R⁴⁶ G⁵ W¹ 2219 R⁴⁷ G⁵ W¹ 2220 R⁴⁹ G⁵ W¹ 2221 R¹ G⁶ W¹ 2222 R² G⁶ W¹ 2223 R⁴ G⁶ W¹ 2224 R⁵ G⁶ W¹ 2225 R⁷ G⁶ W¹ 2226 R⁸ G⁶ W¹ 2227 R¹⁰ G⁶ W¹ 2228 R¹² G⁶ W¹ 2229 R¹⁴ G⁶ W¹ 2230 R¹⁵ G⁶ W¹ 2231 R¹⁹ G⁶ W¹ 2232 R²⁷ G⁶ W¹ 2233 R²⁸ G⁶ W¹ 2234 R³³ G⁶ W¹ 2235 R³⁸ G⁶ W¹ 2236 R³⁹ G⁶ W¹ 2237 R⁴¹ G⁶ W¹ 2238 R⁴⁶ G⁶ W¹ 2239 R⁴⁷ G⁶ W¹ 2240 R⁴⁹ G⁶ W¹ 2241 R¹ G⁹ W¹ 2242 R² G⁹ W¹ 2243 R⁴ G⁹ W¹ 2244 R⁵ G⁹ W¹ 2245 R⁷ G⁹ W¹ 2246 R⁸ G⁹ W¹ 2247 R¹⁰ G⁹ W¹ 2248 R¹² G⁹ W¹ 2249 R¹⁴ G⁹ W¹ 2250 R¹⁵ G⁹ W¹ 2251 R¹⁹ G⁹ W¹ 2252 R²⁷ G⁹ W¹ 2253 R²⁸ G⁹ W¹ 2254 R³³ G⁹ W¹ 2255 R³⁸ G⁹ W¹ 2256 R³⁹ G⁹ W¹ 2257 R⁴¹ G⁹ W¹ 2258 R⁴⁶ G⁹ W¹ 2259 R⁴⁷ G⁹ W¹ 2260 R⁴⁹ G⁹ W¹ 2261 R¹ G¹⁰ W¹ 2262 R² G¹⁰ W¹ 2263 R⁴ G¹⁰ W¹ 2264 R⁵ G¹⁰ W¹ 2265 R⁷ G¹⁰ W¹ 2266 R⁸ G¹⁰ W¹ 2267 R¹⁰ G¹⁰ W¹ 2268 R¹² G¹⁰ W¹ 2269 R¹⁴ G¹⁰ W¹ 2270 R¹⁵ G¹⁰ W¹ 2271 R¹⁹ G¹⁰ W¹ 2272 R²⁷ G¹⁰ W¹ 2273 R²⁸ G¹⁰ W¹ 2274 R³³ G¹⁰ W¹ 2275 R³⁸ G¹⁰ W¹ 2276 R³⁹ G¹⁰ W¹ 2277 R⁴¹ G¹⁰ W¹ 2278 R⁴⁶ G¹⁰ W¹ 2279 R⁴⁷ G¹⁰ W¹ 2280 R⁴⁹ G¹⁰ W¹ 2281 R¹ G²⁵ W¹ 2282 R² G²⁵ W¹ 2283 R⁴ G²⁵ W¹ 2284 R⁵ G²⁵ W¹ 2285 R⁷ G²⁵ W¹ 2286 R⁸ G²⁵ W¹ 2287 R¹⁰ G²⁵ W¹ 2288 R¹² G²⁵ W¹ 2289 R¹⁴ G²⁵ W¹ 2290 R¹⁵ G²⁵ W¹ 2291 R¹⁹ G²⁵ W¹ 2292 R²⁷ G²⁵ W¹ 2293 R²⁸ G²⁵ W¹ 2294 R³³ G²⁵ W¹ 2295 R³⁸ G²⁵ W¹ 2296 R³⁹ G²⁵ W¹ 2297 R⁴¹ G²⁵ W¹ 2298 R⁴⁶ G²⁵ W¹ 2299 R⁴⁷ G²⁵ W¹ 2300 R⁴⁹ G²⁵ W¹ 2301 R¹ G²⁶ W¹ 2302 R² G²⁶ W¹ 2303 R⁴ G²⁶ W¹ 2304 R⁵ G²⁶ W¹ 2305 R⁷ G²⁶ W¹ 2306 R⁸ G²⁶ W¹ 2307 R¹⁰ G²⁶ W¹ 2308 R¹² G²⁶ W¹ 2309 R¹⁴ G²⁶ W¹ 2310 R¹⁵ G²⁶ W¹ 2311 R¹⁹ G²⁶ W¹ 2312 R²⁷ G²⁶ W¹ 2313 R²⁸ G²⁶ W¹ 2314 R³³ G²⁶ W¹ 2315 R³⁸ G²⁶ W¹ 2316 R³⁹ G²⁶ W¹ 2317 R⁴¹ G²⁶ W¹ 2318 R⁴⁶ G²⁶ W¹ 2319 R⁴⁷ G²⁶ W¹ 2320 R⁴⁹ G²⁶ W¹ 2321 R¹ G²⁷ W¹ 2322 R² G²⁷ W¹ 2323 R⁴ G²⁷ W¹ 2324 R⁵ G²⁷ W¹ 2325 R⁷ G²⁷ W¹ 2326 R⁸ G²⁷ W¹ 2327 R¹⁰ G²⁷ W¹ 2328 R¹² G²⁷ W¹ 2329 R¹⁴ G²⁷ W¹ 2330 R¹⁵ G²⁷ W¹ 2331 R¹⁹ G²⁷ W¹ 2332 R²⁷ G²⁷ W¹ 2333 R²⁸ G²⁷ W¹ 2334 R³³ G²⁷ W¹ 2335 R³⁸ G²⁷ W¹ 2336 R³⁹ G²⁷ W¹ 2337 R⁴¹ G²⁷ W¹ 2338 R⁴⁶ G²⁷ W¹ 2339 R⁴⁷ G²⁷ W¹ 2340 R⁴⁹ G²⁷ W¹ 2341 R¹ G²⁸ W¹ 2342 R² G²⁸ W¹ 2343 R⁴ G²⁸ W¹ 2344 R⁵ G²⁸ W¹ 2345 R⁷ G²⁸ W¹ 2346 R⁸ G²⁸ W¹ 2347 R¹⁰ G²⁸ W¹ 2348 R¹² G²⁸ W¹ 2349 R¹⁴ G²⁸ W¹ 2350 R¹⁵ G²⁸ W¹ 2351 R¹⁹ G²⁸ W¹ 2352 R²⁷ G²⁸ W¹ 2353 R²⁸ G²⁸ W¹ 2354 R³³ G²⁸ W¹ 2355 R³⁸ G²⁸ W¹ 2356 R³⁹ G²⁸ W¹ 2357 R⁴¹ G²⁸ W¹ 2358 R⁴⁶ G²⁸ W¹ 2359 R⁴⁷ G²⁸ W¹ 2360 R⁴⁹ G²⁸ W¹ 2361 R¹ G¹ W² 2362 R² G¹ W² 2363 R⁴ G¹ W² 2364 R⁵ G¹ W² 2365 R⁷ G¹ W² 2366 R⁸ G¹ W² 2367 R¹⁰ G¹ W² 2368 R¹² G¹ W² 2369 R¹⁴ G¹ W² 2370 R¹⁵ G¹ W² 2371 R¹⁹ G¹ W² 2372 R²⁷ G¹ W² 2373 R²⁸ G¹ W² 2374 R³³ G¹ W² 2375 R³⁸ G¹ W² 2376 R³⁹ G¹ W² 2377 R⁴¹ G¹ W² 2378 R⁴⁶ G¹ W² 2379 R⁴⁷ G¹ W² 2380 R⁴⁹ G¹ W² 2381 R¹ G³ W² 2382 R² G³ W² 2383 R⁴ G³ W² 2384 R⁵ G³ W² 2385 R⁷ G³ W² 2386 R⁸ G³ W² 2387 R¹⁰ G³ W² 2388 R¹² G³ W² 2389 R¹⁴ G³ W² 2390 R¹⁵ G³ W² 2391 R¹⁹ G³ W² 2392 R²⁷ G³ W² 2393 R²⁸ G³ W² 2394 R³³ G³ W² 2395 R³⁸ G³ W² 2396 R³⁹ G³ W² 2397 R⁴¹ G³ W² 2398 R⁴⁶ G³ W² 2399 R⁴⁷ G³ W² 2400 R⁴⁹ G³ W² 2401 R¹ G⁵ W² 2402 R² G⁵ W² 2403 R⁴ G⁵ W² 2404 R⁵ G⁵ W² 2405 R⁷ G⁵ W² 2406 R⁸ G⁵ W² 2407 R¹⁰ G⁵ W² 2408 R¹² G⁵ W² 2409 R¹⁴ G⁵ W² 2410 R¹⁵ G⁵ W² 2411 R¹⁹ G⁵ W² 2412 R²⁷ G⁵ W² 2413 R²⁸ G⁵ W² 2414 R³³ G⁵ W² 2415 R³⁸ G⁵ W² 2416 R³⁹ G⁵ W² 2417 R⁴¹ G⁵ W² 2418 R⁴⁶ G⁵ W² 2419 R⁴⁷ G⁵ W² 2420 R⁴⁹ G⁵ W² 2421 R¹ G⁶ W² 2422 R² G⁶ W² 2423 R⁴ G⁶ W² 2424 R⁵ G⁶ W² 2425 R⁷ G⁶ W² 2426 R⁸ G⁶ W² 2427 R¹⁰ G⁶ W² 2428 R¹² G⁶ W² 2429 R¹⁴ G⁶ W² 2430 R¹⁵ G⁶ W² 2431 R¹⁹ G⁶ W² 2432 R²⁷ G⁶ W² 2433 R²⁸ G⁶ W² 2434 R³³ G⁶ W² 2435 R³⁸ G⁶ W² 2436 R³⁹ G⁶ W² 2437 R⁴¹ G⁶ W² 2438 R⁴⁶ G⁶ W² 2439 R⁴⁷ G⁶ W² 2440 R⁴⁹ G⁶ W² 2441 R¹ G⁹ W² 2442 R² G⁹ W² 2443 R⁴ G⁹ W² 2444 R⁵ G⁹ W² 2445 R⁷ G⁹ W² 2446 R⁸ G⁹ W² 2447 R¹⁰ G⁹ W² 2448 R¹² G⁹ W² 2449 R¹⁴ G⁹ W² 2450 R¹⁵ G⁹ W² 2451 R¹⁹ G⁹ W² 2452 R²⁷ G⁹ W² 2453 R²⁸ G⁹ W² 2454 R³³ G⁹ W² 2455 R³⁸ G⁹ W² 2456 R³⁹ G⁹ W² 2457 R⁴¹ G⁹ W² 2458 R⁴⁶ G⁹ W² 2459 R⁴⁷ G⁹ W² 2460 R⁴⁹ G⁹ W² 2461 R¹ G¹⁰ W² 2462 R² G¹⁰ W² 2463 R⁴ G¹⁰ W² 2464 R⁵ G¹⁰ W² 2465 R⁷ G¹⁰ W² 2466 R⁸ G¹⁰ W² 2467 R¹⁰ G¹⁰ W² 2468 R¹² G¹⁰ W² 2469 R¹⁴ G¹⁰ W² 2470 R¹⁵ G¹⁰ W² 2471 R¹⁹ G¹⁰ W² 2472 R²⁷ G¹⁰ W² 2473 R²⁸ G¹⁰ W² 2474 R³³ G¹⁰ W² 2475 R³⁸ G¹⁰ W² 2476 R³⁹ G¹⁰ W² 2477 R⁴¹ G¹⁰ W² 2478 R⁴⁶ G¹⁰ W² 2479 R⁴⁷ G¹⁰ W² 2480 R⁴⁹ G¹⁰ W² 2481 R¹ G²⁵ W² 2482 R² G²⁵ W² 2483 R⁴ G²⁵ W² 2484 R⁵ G²⁵ W² 2485 R⁷ G²⁵ W² 2486 R⁸ G²⁵ W² 2487 R¹⁰ G²⁵ W² 2488 R¹² G²⁵ W² 2489 R¹⁴ G²⁵ W² 2490 R¹⁵ G²⁵ W² 2491 R¹⁹ G²⁵ W² 2492 R²⁷ G²⁵ W² 2493 R²⁸ G²⁵ W² 2494 R³³ G²⁵ W² 2495 R³⁸ G²⁵ W² 2496 R³⁹ G²⁵ W² 2497 R⁴¹ G²⁵ W² 2498 R⁴⁶ G²⁵ W² 2499 R⁴⁷ G²⁵ W² 2500 R⁴⁹ G²⁵ W² 2501 R¹ G²⁶ W² 2502 R² G²⁶ W² 2503 R⁴ G²⁶ W² 2504 R⁵ G²⁶ W² 2505 R⁷ G²⁶ W² 2506 R⁸ G²⁶ W² 2507 R¹⁰ G²⁶ W² 2508 R¹² G²⁶ W² 2509 R¹⁴ G²⁶ W² 2510 R¹⁵ G²⁶ W² 2511 R¹⁹ G²⁶ W² 2512 R²⁷ G²⁶ W² 2513 R²⁸ G²⁶ W² 2514 R³³ G²⁶ W² 2515 R³⁸ G²⁶ W² 2516 R³⁹ G²⁶ W² 2517 R⁴¹ G²⁶ W² 2518 R⁴⁶ G²⁶ W² 2519 R⁴⁷ G²⁶ W² 2520 R⁴⁹ G²⁶ W² 2521 R¹ G²⁷ W² 2522 R² G²⁷ W² 2523 R⁴ G²⁷ W² 2524 R⁵ G²⁷ W² 2525 R⁷ G²⁷ W² 2526 R⁸ G²⁷ W² 2527 R¹⁰ G²⁷ W² 2528 R¹² G²⁷ W² 2529 R¹⁴ G²⁷ W² 2530 R¹⁵ G²⁷ W² 2531 R¹⁹ G²⁷ W² 2532 R²⁷ G²⁷ W² 2533 R²⁸ G²⁷ W² 2534 R³³ G²⁷ W² 2535 R³⁸ G²⁷ W² 2536 R³⁹ G²⁷ W² 2537 R⁴¹ G²⁷ W² 2538 R⁴⁶ G²⁷ W² 2539 R⁴⁷ G²⁷ W² 2540 R⁴⁹ G²⁷ W² 2541 R¹ G²⁸ W² 2542 R² G²⁸ W² 2543 R⁴ G²⁸ W² 2544 R⁵ G²⁸ W² 2545 R⁷ G²⁸ W² 2546 R⁸ G²⁸ W² 2547 R¹⁰ G²⁸ W² 2548 R¹² G²⁸ W² 2549 R¹⁴ G²⁸ W² 2550 R¹⁵ G²⁸ W² 2551 R¹⁹ G²⁸ W² 2552 R²⁷ G²⁸ W² 2553 R²⁸ G²⁸ W² 2554 R³³ G²⁸ W² 2555 R³⁸ G²⁸ W² 2556 R³⁹ G²⁸ W² 2557 R⁴¹ G²⁸ W² 2558 R⁴⁶ G²⁸ W² 2559 R⁴⁷ G²⁸ W² 2560 R⁴⁹ G²⁸ W² 2561 R¹ G¹ W⁵ 2562 R² G¹ W⁵ 2563 R⁴ G¹ W⁵ 2564 R⁵ G¹ W⁵ 2565 R⁷ G¹ W⁵ 2566 R⁸ G¹ W⁵ 2567 R¹⁰ G¹ W⁵ 2568 R¹² G¹ W⁵ 2569 R¹⁴ G¹ W⁵ 2570 R¹⁵ G¹ W⁵ 2571 R¹⁹ G¹ W⁵ 2572 R²⁷ G¹ W⁵ 2573 R²⁸ G¹ W⁵ 2574 R³³ G¹ W⁵ 2575 R³⁸ G¹ W⁵ 2576 R³⁹ G¹ W⁵ 2577 R⁴¹ G¹ W⁵ 2578 R⁴⁶ G¹ W⁵ 2579 R⁴⁷ G¹ W⁵ 2580 R⁴⁹ G¹ W⁵ 2581 R¹ G³ W⁵ 2582 R² G³ W⁵ 2583 R⁴ G³ W⁵ 2584 R⁵ G³ W⁵ 2585 R⁷ G³ W⁵ 2586 R⁸ G³ W⁵ 2587 R¹⁰ G³ W⁵ 2588 R¹² G³ W⁵ 2589 R¹⁴ G³ W⁵ 2590 R¹⁵ G³ W⁵ 2591 R¹⁹ G³ W⁵ 2592 R²⁷ G³ W⁵ 2593 R²⁸ G³ W⁵ 2594 R³³ G³ W⁵ 2595 R³⁸ G³ W⁵ 2596 R³⁹ G³ W⁵ 2597 R⁴¹ G³ W⁵ 2598 R⁴⁶ G³ W⁵ 2599 R⁴⁷ G³ W⁵ 2600 R⁴⁹ G³ W⁵ 2601 R¹ G⁵ W⁵ 2602 R² G⁵ W⁵ 2603 R⁴ G⁵ W⁵ 2604 R⁵ G⁵ W⁵ 2605 R⁷ G⁵ W⁵ 2606 R⁸ G⁵ W⁵ 2607 R¹⁰ G⁵ W⁵ 2608 R¹² G⁵ W⁵ 2609 R¹⁴ G⁵ W⁵ 2610 R¹⁵ G⁵ W⁵ 2611 R¹⁹ G⁵ W⁵ 2612 R²⁷ G⁵ W⁵ 2613 R²⁸ G⁵ W⁵ 2614 R³³ G⁵ W⁵ 2615 R³⁸ G⁵ W⁵ 2616 R³⁹ G⁵ W⁵ 2617 R⁴¹ G⁵ W⁵ 2618 R⁴⁶ G⁵ W⁵ 2619 R⁴⁷ G⁵ W⁵ 2620 R⁴⁹ G⁵ W⁵ 2621 R¹ G⁶ W⁵ 2622 R² G⁶ W⁵ 2623 R⁴ G⁶ W⁵ 2624 R⁵ G⁶ W⁵ 2625 R⁷ G⁶ W⁵ 2626 R⁸ G⁶ W⁵ 2627 R¹⁰ G⁶ W⁵ 2628 R¹² G⁶ W⁵ 2629 R¹⁴ G⁶ W⁵ 2630 R¹⁵ G⁶ W⁵ 2631 R¹⁹ G⁶ W⁵ 2632 R²⁷ G⁶ W⁵ 2633 R²⁸ G⁶ W⁵ 2634 R³³ G⁶ W⁵ 2635 R³⁸ G⁶ W⁵ 2636 R³⁹ G⁶ W⁵ 2637 R⁴¹ G⁶ W⁵ 2638 R⁴⁶ G⁶ W⁵ 2639 R⁴⁷ G⁶ W⁵ 2640 R⁴⁹ G⁶ W⁵ 2641 R¹ G⁹ W⁵ 2642 R² G⁹ W⁵ 2643 R⁴ G⁹ W⁵ 2644 R⁵ G⁹ W⁵ 2645 R⁷ G⁹ W⁵ 2646 R⁸ G⁹ W⁵ 2647 R¹⁰ G⁹ W⁵ 2648 R¹² G⁹ W⁵ 2649 R¹⁴ G⁹ W⁵ 2650 R¹⁵ G⁹ W⁵ 2651 R¹⁹ G⁹ W⁵ 2652 R²⁷ G⁹ W⁵ 2653 R²⁸ G⁹ W⁵ 2654 R³³ G⁹ W⁵ 2655 R³⁸ G⁹ W⁵ 2656 R³⁹ G⁹ W⁵ 2657 R⁴¹ G⁹ W⁵ 2658 R⁴⁶ G⁹ W⁵ 2659 R⁴⁷ G⁹ W⁵ 2660 R⁴⁹ G⁹ W⁵ 2661 R¹ G¹⁰ W⁵ 2662 R² G¹⁰ W⁵ 2663 R⁴ G¹⁰ W⁵ 2664 R⁵ G¹⁰ W⁵ 2665 R⁷ G¹⁰ W⁵ 2666 R⁸ G¹⁰ W⁵ 2667 R¹⁰ G¹⁰ W⁵ 2668 R¹² G¹⁰ W⁵ 2669 R¹⁴ G¹⁰ W⁵ 2670 R¹⁵ G¹⁰ W⁵ 2671 R¹⁹ G¹⁰ W⁵ 2672 R²⁷ G¹⁰ W⁵ 2673 R²⁸ G¹⁰ W⁵ 2674 R³³ G¹⁰ W⁵ 2675 R³⁸ G¹⁰ W⁵ 2676 R³⁹ G¹⁰ W⁵ 2677 R⁴¹ G¹⁰ W⁵ 2678 R⁴⁶ G¹⁰ W⁵ 2679 R⁴⁷ G¹⁰ W⁵ 2680 R⁴⁹ G¹⁰ W⁵ 2681 R¹ G²⁵ W⁵ 2682 R² G²⁵ W⁵ 2683 R⁴ G²⁵ W⁵ 2684 R⁵ G²⁵ W⁵ 2685 R⁷ G²⁵ W⁵ 2686 R⁸ G²⁵ W⁵ 2687 R¹⁰ G²⁵ W⁵ 2688 R¹² G²⁵ W⁵ 2689 R¹⁴ G²⁵ W⁵ 2690 R¹⁵ G²⁵ W⁵ 2691 R¹⁹ G²⁵ W⁵ 2692 R²⁷ G²⁵ W⁵ 2693 R²⁸ G²⁵ W⁵ 2694 R³³ G²⁵ W⁵ 2695 R³⁸ G²⁵ W⁵ 2696 R³⁹ G²⁵ W⁵ 2697 R⁴¹ G²⁵ W⁵ 2698 R⁴⁶ G²⁵ W⁵ 2699 R⁴⁷ G²⁵ W⁵ 2700 R⁴⁹ G²⁵ W⁵ 2701 R¹ G²⁶ W⁵ 2702 R² G²⁶ W⁵ 2703 R⁴ G²⁶ W⁵ 2704 R⁵ G²⁶ W⁵ 2705 R⁷ G²⁶ W⁵ 2706 R⁸ G²⁶ W⁵ 2707 R¹⁰ G²⁶ W⁵ 2708 R¹² G²⁶ W⁵ 2709 R¹⁴ G²⁶ W⁵ 2710 R¹⁵ G²⁶ W⁵ 2711 R¹⁹ G²⁶ W⁵ 2712 R²⁷ G²⁶ W⁵ 2713 R²⁸ G²⁶ W⁵ 2714 R³³ G²⁶ W⁵ 2715 R³⁸ G²⁶ W⁵ 2716 R³⁹ G²⁶ W⁵ 2717 R⁴¹ G²⁶ W⁵ 2718 R⁴⁶ G²⁶ W⁵ 2719 R⁴⁷ G²⁶ W⁵ 2720 R⁴⁹ G²⁶ W⁵ 2721 R¹ G²⁷ W⁵ 2722 R² G²⁷ W⁵ 2723 R⁴ G²⁷ W⁵ 2724 R⁵ G²⁷ W⁵ 2725 R⁷ G²⁷ W⁵ 2726 R⁸ G²⁷ W⁵ 2727 R¹⁰ G²⁷ W⁵ 2728 R¹² G²⁷ W⁵ 2729 R¹⁴ G²⁷ W⁵ 2730 R¹⁵ G²⁷ W⁵ 2731 R¹⁹ G²⁷ W⁵ 2732 R²⁷ G²⁷ W⁵ 2733 R²⁸ G²⁷ W⁵ 2734 R³³ G²⁷ W⁵ 2735 R³⁸ G²⁷ W⁵ 2736 R³⁹ G²⁷ W⁵ 2737 R⁴¹ G²⁷ W⁵ 2738 R⁴⁶ G²⁷ W⁵ 2739 R⁴⁷ G²⁷ W⁵ 2740 R⁴⁹ G²⁷ W⁵ 2741 R¹ G²⁸ W⁵ 2742 R² G²⁸ W⁵ 2743 R⁴ G²⁸ W⁵ 2744 R⁵ G²⁸ W⁵ 2745 R⁷ G²⁸ W⁵ 2746 R⁸ G²⁸ W⁵ 2747 R¹⁰ G²⁸ W⁵ 2748 R¹² G²⁸ W⁵ 2749 R¹⁴ G²⁸ W⁵ 2750 R¹⁵ G²⁸ W⁵ 2751 R¹⁹ G²⁸ W⁵ 2752 R²⁷ G²⁸ W⁵ 2753 R²⁸ G²⁸ W⁵ 2754 R³³ G²⁸ W⁵ 2755 R³⁸ G²⁸ W⁵ 2756 R³⁹ G²⁸ W⁵ 2757 R⁴¹ G²⁸ W⁵ 2758 R⁴⁶ G²⁸ W⁵ 2759 R⁴⁷ G²⁸ W⁵ 2760 R⁴⁹ G²⁸ W⁵ 2761 R¹ G¹ W⁶ 2762 R² G¹ W⁶ 2763 R⁴ G¹ W⁶ 2764 R⁵ G¹ W⁶ 2765 R⁷ G¹ W⁶ 2766 R⁸ G¹ W⁶ 2767 R¹⁰ G¹ W⁶ 2768 R¹² G¹ W⁶ 2769 R¹⁴ G¹ W⁶ 2770 R¹⁵ G¹ W⁶ 2771 R¹⁹ G¹ W⁶ 2772 R²⁷ G¹ W⁶ 2773 R²⁸ G¹ W⁶ 2774 R³³ G¹ W⁶ 2775 R³⁸ G¹ W⁶ 2776 R³⁹ G¹ W⁶ 2777 R⁴¹ G¹ W⁶ 2778 R⁴⁶ G¹ W⁶ 2779 R⁴⁷ G¹ W⁶ 2780 R⁴⁹ G¹ W⁶ 2781 R¹ G³ W⁶ 2782 R² G³ W⁶ 2783 R⁴ G³ W⁶ 2784 R⁵ G³ W⁶ 2785 R⁷ G³ W⁶ 2786 R⁸ G³ W⁶ 2787 R¹⁰ G³ W⁶ 2788 R¹² G³ W⁶ 2789 R¹⁴ G³ W⁶ 2790 R¹⁵ G³ W⁶ 2791 R¹⁹ G³ W⁶ 2792 R²⁷ G³ W⁶ 2793 R²⁸ G³ W⁶ 2794 R³³ G³ W⁶ 2795 R³⁸ G³ W⁶ 2796 R³⁹ G³ W⁶ 2797 R⁴¹ G³ W⁶ 2798 R⁴⁶ G³ W⁶ 2799 R⁴⁷ G³ W⁶ 2800 R⁴⁹ G³ W⁶ 2801 R¹ G⁵ W⁶ 2802 R² G⁵ W⁶ 2803 R⁴ G⁵ W⁶ 2804 R⁵ G⁵ W⁶ 2805 R⁷ G⁵ W⁶ 2806 R⁸ G⁵ W⁶ 2807 R¹⁰ G⁵ W⁶ 2808 R¹² G⁵ W⁶ 2809 R¹⁴ G⁵ W⁶ 2810 R¹⁵ G⁵ W⁶ 2811 R¹⁹ G⁵ W⁶ 2812 R²⁷ G⁵ W⁶ 2813 R²⁸ G⁵ W⁶ 2814 R³³ G⁵ W⁶ 2815 R³⁸ G⁵ W⁶ 2816 R³⁹ G⁵ W⁶ 2817 R⁴¹ G⁵ W⁶ 2818 R⁴⁶ G⁵ W⁶ 2819 R⁴⁷ G⁵ W⁶ 2820 R⁴⁹ G⁵ W⁶ 2821 R¹ G⁶ W⁶ 2822 R² G⁶ W⁶ 2823 R⁴ G⁶ W⁶ 2824 R⁵ G⁶ W⁶ 2825 R⁷ G⁶ W⁶ 2826 R⁸ G⁶ W⁶ 2827 R¹⁰ G⁶ W⁶ 2828 R¹² G⁶ W⁶ 2829 R¹⁴ G⁶ W⁶ 2830 R¹⁵ G⁶ W⁶ 2831 R¹⁹ G⁶ W⁶ 2832 R²⁷ G⁶ W⁶ 2833 R²⁸ G⁶ W⁶ 2834 R³³ G⁶ W⁶ 2835 R³⁸ G⁶ W⁶ 2836 R³⁹ G⁶ W⁶ 2837 R⁴¹ G⁶ W⁶ 2838 R⁴⁶ G⁶ W⁶ 2839 R⁴⁷ G⁶ W⁶ 2840 R⁴⁹ G⁶ W⁶ 2841 R¹ G⁹ W⁶ 2842 R² G⁹ W⁶ 2843 R⁴ G⁹ W⁶ 2844 R⁵ G⁹ W⁶ 2845 R⁷ G⁹ W⁶ 2846 R⁸ G⁹ W⁶ 2847 R¹⁰ G⁹ W⁶ 2848 R¹² G⁹ W⁶ 2849 R¹⁴ G⁹ W⁶ 2850 R¹⁵ G⁹ W⁶ 2851 R¹⁹ G⁹ W⁶ 2852 R²⁷ G⁹ W⁶ 2853 R²⁸ G⁹ W⁶ 2854 R³³ G⁹ W⁶ 2855 R³⁸ G⁹ W⁶ 2856 R³⁹ G⁹ W⁶ 2857 R⁴¹ G⁹ W⁶ 2858 R⁴⁶ G⁹ W⁶ 2859 R⁴⁷ G⁹ W⁶ 2860 R⁴⁹ G⁹ W⁶ 2861 R¹ G¹⁰ W⁶ 2862 R² G¹⁰ W⁶ 2863 R⁴ G¹⁰ W⁶ 2864 R⁵ G¹⁰ W⁶ 2865 R⁷ G¹⁰ W⁶ 2866 R⁸ G¹⁰ W⁶ 2867 R¹⁰ G¹⁰ W⁶ 2868 R¹² G¹⁰ W⁶ 2869 R¹⁴ G¹⁰ W⁶ 2870 R¹⁵ G¹⁰ W⁶ 2871 R¹⁹ G¹⁰ W⁶ 2872 R²⁷ G¹⁰ W⁶ 2873 R²⁸ G¹⁰ W⁶ 2874 R³³ G¹⁰ W⁶ 2875 R³⁸ G¹⁰ W⁶ 2876 R³⁹ G¹⁰ W⁶ 2877 R⁴¹ G¹⁰ W⁶ 2878 R⁴⁶ G¹⁰ W⁶ 2879 R⁴⁷ G¹⁰ W⁶ 2880 R⁴⁹ G¹⁰ W⁶ 2881 R¹ G²⁵ W⁶ 2882 R² G²⁵ W⁶ 2883 R⁴ G²⁵ W⁶ 2884 R⁵ G²⁵ W⁶ 2885 R⁷ G²⁵ W⁶ 2886 R⁸ G²⁵ W⁶ 2887 R¹⁰ G²⁵ W⁶ 2888 R¹² G²⁵ W⁶ 2889 R¹⁴ G²⁵ W⁶ 2890 R¹⁵ G²⁵ W⁶ 2891 R¹⁹ G²⁵ W⁶ 2892 R²⁷ G²⁵ W⁶ 2893 R²⁸ G²⁵ W⁶ 2894 R³³ G²⁵ W⁶ 2895 R³⁸ G²⁵ W⁶ 2896 R³⁹ G²⁵ W⁶ 2897 R⁴¹ G²⁵ W⁶ 2898 R⁴⁶ G²⁵ W⁶ 2899 R⁴⁷ G²⁵ W⁶ 2900 R⁴⁹ G²⁵ W⁶ 2901 R¹ G²⁶ W⁶ 2902 R² G²⁶ W⁶ 2903 R⁴ G²⁶ W⁶ 2904 R⁵ G²⁶ W⁶ 2905 R⁷ G²⁶ W⁶ 2906 R⁸ G²⁶ W⁶ 2907 R¹⁰ G²⁶ W⁶ 2908 R¹² G²⁶ W⁶ 2909 R¹⁴ G²⁶ W⁶ 2910 R¹⁵ G²⁶ W⁶ 2911 R¹⁹ G²⁶ W⁶ 2912 R²⁷ G²⁶ W⁶ 2913 R²⁸ G²⁶ W⁶ 2914 R³³ G²⁶ W⁶ 2915 R³⁸ G²⁶ W⁶ 2916 R³⁹ G²⁶ W⁶ 2917 R⁴¹ G²⁶ W⁶ 2918 R⁴⁶ G²⁶ W⁶ 2919 R⁴⁷ G²⁶ W⁶ 2920 R⁴⁹ G²⁶ W⁶ 2921 R¹ G²⁷ W⁶ 2922 R² G²⁷ W⁶ 2923 R⁴ G²⁷ W⁶ 2924 R⁵ G²⁷ W⁶ 2925 R⁷ G²⁷ W⁶ 2926 R⁸ G²⁷ W⁶ 2927 R¹⁰ G²⁷ W⁶ 2928 R¹² G²⁷ W⁶ 2929 R¹⁴ G²⁷ W⁶ 2930 R¹⁵ G²⁷ W⁶ 2931 R¹⁹ G²⁷ W⁶ 2932 R²⁷ G²⁷ W⁶ 2933 R²⁸ G²⁷ W⁶ 2934 R³³ G²⁷ W⁶ 2935 R³⁸ G²⁷ W⁶ 2936 R³⁹ G²⁷ W⁶ 2937 R⁴¹ G²⁷ W⁶ 2938 R⁴⁶ G²⁷ W⁶ 2939 R⁴⁷ G²⁷ W⁶ 2940 R⁴⁹ G²⁷ W⁶ 2941 R¹ G²⁸ W⁶ 2942 R² G²⁸ W⁶ 2943 R⁴ G²⁸ W⁶ 2944 R⁵ G²⁸ W⁶ 2945 R⁷ G²⁸ W⁶ 2946 R⁸ G²⁸ W⁶ 2947 R¹⁰ G²⁸ W⁶ 2948 R¹² G²⁸ W⁶ 2949 R¹⁴ G²⁸ W⁶ 2950 R¹⁵ G²⁸ W⁶ 2951 R¹⁹ G²⁸ W⁶ 2952 R²⁷ G²⁸ W⁶ 2953 R²⁸ G²⁸ W⁶ 2954 R³³ G²⁸ W⁶ 2955 R³⁸ G²⁸ W⁶ 2956 R³⁹ G²⁸ W⁶ 2957 R⁴¹ G²⁸ W⁶ 2958 R⁴⁶ G²⁸ W⁶ 2959 R⁴⁷ G²⁸ W⁶ 2960 R⁴⁹ G²⁸ W⁶ 2961 R¹ G¹ W¹¹ 2962 R² G¹ W¹¹ 2963 R⁴ G¹ W¹¹ 2964 R⁵ G¹ W¹¹ 2965 R⁷ G¹ W¹¹ 2966 R⁸ G¹ W¹¹ 2967 R¹⁰ G¹ W¹¹ 2968 R¹² G¹ W¹¹ 2969 R¹⁴ G¹ W¹¹ 2970 R¹⁵ G¹ W¹¹ 2971 R¹⁹ G¹ W¹¹ 2972 R²⁷ G¹ W¹¹ 2973 R²⁸ G¹ W¹¹ 2974 R³³ G¹ W¹¹ 2975 R³⁸ G¹ W¹¹ 2976 R³⁹ G¹ W¹¹ 2977 R⁴¹ G¹ W¹¹ 2978 R⁴⁶ G¹ W¹¹ 2979 R⁴⁷ G¹ W¹¹ 2980 R⁴⁹ G¹ W¹¹ 2981 R¹ G³ W¹¹ 2982 R² G³ W¹¹ 2983 R⁴ G³ W¹¹ 2984 R⁵ G³ W¹¹ 2985 R⁷ G³ W¹¹ 2986 R⁸ G³ W¹¹ 2987 R¹⁰ G³ W¹¹ 2988 R¹² G³ W¹¹ 2989 R¹⁴ G³ W¹¹ 2990 R¹⁵ G³ W¹¹ 2991 R¹⁹ G³ W¹¹ 2992 R²⁷ G³ W¹¹ 2993 R²⁸ G³ W¹¹ 2994 R³³ G³ W¹¹ 2995 R³⁸ G³ W¹¹ 2996 R³⁹ G³ W¹¹ 2997 R⁴¹ G³ W¹¹ 2998 R⁴⁶ G³ W¹¹ 2999 R⁴⁷ G³ W¹¹ 3000 R⁴⁹ G³ W¹¹ 3001 R¹ G⁵ W¹¹ 3002 R² G⁵ W¹¹ 3003 R⁴ G⁵ W¹¹ 3004 R⁵ G⁵ W¹¹ 3005 R⁷ G⁵ W¹¹ 3006 R⁸ G⁵ W¹¹ 3007 R¹⁰ G⁵ W¹¹ 3008 R¹² G⁵ W¹¹ 3009 R¹⁴ G⁵ W¹¹ 3010 R¹⁵ G⁵ W¹¹ 3011 R¹⁹ G⁵ W¹¹ 3012 R²⁷ G⁵ W¹¹ 3013 R²⁸ G⁵ W¹¹ 3014 R³³ G⁵ W¹¹ 3015 R³⁸ G⁵ W¹¹ 3016 R³⁹ G⁵ W¹¹ 3017 R⁴¹ G⁵ W¹¹ 3018 R⁴⁶ G⁵ W¹¹ 3019 R⁴⁷ G⁵ W¹¹ 3020 R⁴⁹ G⁵ W¹¹ 3021 R¹ G⁶ W¹¹ 3022 R² G⁶ W¹¹ 3023 R⁴ G⁶ W¹¹ 3024 R⁵ G⁶ W¹¹ 3025 R⁷ G⁶ W¹¹ 3026 R⁸ G⁶ W¹¹ 3027 R¹⁰ G⁶ W¹¹ 3028 R¹² G⁶ W¹¹ 3029 R¹⁴ G⁶ W¹¹ 3030 R¹⁵ G⁶ W¹¹ 3031 R¹⁹ G⁶ W¹¹ 3032 R²⁷ G⁶ W¹¹ 3033 R²⁸ G⁶ W¹¹ 3034 R³³ G⁶ W¹¹ 3035 R³⁸ G⁶ W¹¹ 3036 R³⁹ G⁶ W¹¹ 3037 R⁴¹ G⁶ W¹¹ 3038 R⁴⁶ G⁶ W¹¹ 3039 R⁴⁷ G⁶ W¹¹ 3040 R⁴⁹ G⁶ W¹¹ 3041 R¹ G⁹ W¹¹ 3042 R² G⁹ W¹¹ 3043 R⁴ G⁹ W¹¹ 3044 R⁵ G⁹ W¹¹ 3045 R⁷ G⁹ W¹¹ 3046 R⁸ G⁹ W¹¹ 3047 R¹⁰ G⁹ W¹¹ 3048 R¹² G⁹ W¹¹ 3049 R¹⁴ G⁹ W¹¹ 3050 R¹⁵ G⁹ W¹¹ 3051 R¹⁹ G⁹ W¹¹ 3052 R²⁷ G⁹ W¹¹ 3053 R²⁸ G⁹ W¹¹ 3054 R³³ G⁹ W¹¹ 3055 R³⁸ G⁹ W¹¹ 3056 R³⁹ G⁹ W¹¹ 3057 R⁴¹ G⁹ W¹¹ 3058 R⁴⁶ G⁹ W¹¹ 3059 R⁴⁷ G⁹ W¹¹ 3060 R⁴⁹ G⁹ W¹¹ 3061 R¹ G¹⁰ W¹¹ 3062 R² G¹⁰ W¹¹ 3063 R⁴ G¹⁰ W¹¹ 3064 R⁵ G¹⁰ W¹¹ 3065 R⁷ G¹⁰ W¹¹ 3066 R⁸ G¹⁰ W¹¹ 3067 R¹⁰ G¹⁰ W¹¹ 3068 R¹² G¹⁰ W¹¹ 3069 R¹⁴ G¹⁰ W¹¹ 3070 R¹⁵ G¹⁰ W¹¹ 3071 R¹⁹ G¹⁰ W¹¹ 3072 R²⁷ G¹⁰ W¹¹ 3073 R²⁸ G¹⁰ W¹¹ 3074 R³³ G¹⁰ W¹¹ 3075 R³⁸ G¹⁰ W¹¹ 3076 R³⁹ G¹⁰ W¹¹ 3077 R⁴¹ G¹⁰ W¹¹ 3078 R⁴⁶ G¹⁰ W¹¹ 3079 R⁴⁷ G¹⁰ W¹¹ 3080 R⁴⁹ G¹⁰ W¹¹ 3081 R¹ G²⁵ W¹¹ 3082 R² G²⁵ W¹¹ 3083 R⁴ G²⁵ W¹¹ 3084 R⁵ G²⁵ W¹¹ 3085 R⁷ G²⁵ W¹¹ 3086 R⁸ G²⁵ W¹¹ 3087 R¹⁰ G²⁵ W¹¹ 3088 R¹² G²⁵ W¹¹ 3089 R¹⁴ G²⁵ W¹¹ 3090 R¹⁵ G²⁵ W¹¹ 3091 R¹⁹ G²⁵ W¹¹ 3092 R²⁷ G²⁵ W¹¹ 3093 R²⁸ G²⁵ W¹¹ 3094 R³³ G²⁵ W¹¹ 3095 R³⁸ G²⁵ W¹¹ 3096 R³⁹ G²⁵ W¹¹ 3097 R⁴¹ G²⁵ W¹¹ 3098 R⁴⁶ G²⁵ W¹¹ 3099 R⁴⁷ G²⁵ W¹¹ 3100 R⁴⁹ G²⁵ W¹¹ 3101 R¹ G²⁶ W¹¹ 3102 R² G²⁶ W¹¹ 3103 R⁴ G²⁶ W¹¹ 3104 R⁵ G²⁶ W¹¹ 3105 R⁷ G²⁶ W¹¹ 3106 R⁸ G²⁶ W¹¹ 3107 R¹⁰ G²⁶ W¹¹ 3108 R¹² G²⁶ W¹¹ 3109 R¹⁴ G²⁶ W¹¹ 3110 R¹⁵ G²⁶ W¹¹ 3111 R¹⁹ G²⁶ W¹¹ 3112 R²⁷ G²⁶ W¹¹ 3113 R²⁸ G²⁶ W¹¹ 3114 R³³ G²⁶ W¹¹ 3115 R³⁸ G²⁶ W¹¹ 3116 R³⁹ G²⁶ W¹¹ 3117 R⁴¹ G²⁶ W¹¹ 3118 R⁴⁶ G²⁶ W¹¹ 3119 R⁴⁷ G²⁶ W¹¹ 3120 R⁴⁹ G²⁶ W¹¹ 3121 R¹ G²⁷ W¹¹ 3122 R² G²⁷ W¹¹ 3123 R⁴ G²⁷ W¹¹ 3124 R⁵ G²⁷ W¹¹ 3125 R⁷ G²⁷ W¹¹ 3126 R⁸ G²⁷ W¹¹ 3127 R¹⁰ G²⁷ W¹¹ 3128 R¹² G²⁷ W¹¹ 3129 R¹⁴ G²⁷ W¹¹ 3130 R¹⁵ G²⁷ W¹¹ 3131 R¹⁹ G²⁷ W¹¹ 3132 R²⁷ G²⁷ W¹¹ 3133 R²⁸ G²⁷ W¹¹ 3134 R³³ G²⁷ W¹¹ 3135 R³⁸ G²⁷ W¹¹ 3136 R³⁹ G²⁷ W¹¹ 3137 R⁴¹ G²⁷ W¹¹ 3138 R⁴⁶ G²⁷ W¹¹ 3139 R⁴⁷ G²⁷ W¹¹ 3140 R⁴⁹ G²⁷ W¹¹ 3141 R¹ G²⁸ W¹¹ 3142 R² G²⁸ W¹¹ 3143 R⁴ G²⁸ W¹¹ 3144 R⁵ G²⁸ W¹¹ 3145 R⁷ G²⁸ W¹¹ 3146 R⁸ G²⁸ W¹¹ 3147 R¹⁰ G²⁸ W¹¹ 3148 R¹² G²⁸ W¹¹ 3149 R¹⁴ G²⁸ W¹¹ 3150 R¹⁵ G²⁸ W¹¹ 3151 R¹⁹ G²⁸ W¹¹ 3152 R²⁷ G²⁸ W¹¹ 3153 R²⁸ G²⁸ W¹¹ 3154 R³³ G²⁸ W¹¹ 3155 R³⁸ G²⁸ W¹¹ 3156 R³⁹ G²⁸ W¹¹ 3157 R⁴¹ G²⁸ W¹¹ 3158 R⁴⁶ G²⁸ W¹¹ 3159 R⁴⁷ G²⁸ W¹¹ 3160 R⁴⁹ G²⁸ W¹¹ 3161 R¹ G¹ W¹⁷ 3162 R² G¹ W¹⁷ 3163 R⁴ G¹ W¹⁷ 3164 R⁵ G¹ W¹⁷ 3165 R⁷ G¹ W¹⁷ 3166 R⁸ G¹ W¹⁷ 3167 R¹⁰ G¹ W¹⁷ 3168 R¹² G¹ W¹⁷ 3169 R¹⁴ G¹ W¹⁷ 3170 R¹⁵ G¹ W¹⁷ 3171 R¹⁹ G¹ W¹⁷ 3172 R²⁷ G¹ W¹⁷ 3173 R²⁸ G¹ W¹⁷ 3174 R³³ G¹ W¹⁷ 3175 R³⁸ G¹ W¹⁷ 3176 R³⁹ G¹ W¹⁷ 3177 R⁴¹ G¹ W¹⁷ 3178 R⁴⁶ G¹ W¹⁷ 3179 R⁴⁷ G¹ W¹⁷ 3180 R⁴⁹ G¹ W¹⁷ 3181 R¹ G³ W¹⁷ 3182 R² G³ W¹⁷ 3183 R⁴ G³ W¹⁷ 3184 R⁵ G³ W¹⁷ 3185 R⁷ G³ W¹⁷ 3186 R⁸ G³ W¹⁷ 3187 R¹⁰ G³ W¹⁷ 3188 R¹² G³ W¹⁷ 3189 R¹⁴ G³ W¹⁷ 3190 R¹⁵ G³ W¹⁷ 3191 R¹⁹ G³ W¹⁷ 3192 R²⁷ G³ W¹⁷ 3193 R²⁸ G³ W¹⁷ 3194 R³³ G³ W¹⁷ 3195 R³⁸ G³ W¹⁷ 3196 R³⁹ G³ W¹⁷ 3197 R⁴¹ G³ W¹⁷ 3198 R⁴⁶ G³ W¹⁷ 3199 R⁴⁷ G³ W¹⁷ 3200 R⁴⁹ G³ W¹⁷ 3201 R¹ G⁵ W¹⁷ 3202 R² G⁵ W¹⁷ 3203 R⁴ G⁵ W¹⁷ 3204 R⁵ G⁵ W¹⁷ 3205 R⁷ G⁵ W¹⁷ 3206 R⁸ G⁵ W¹⁷ 3207 R¹⁰ G⁵ W¹⁷ 3208 R¹² G⁵ W¹⁷ 3209 R¹⁴ G⁵ W¹⁷ 3210 R¹⁵ G⁵ W¹⁷ 3211 R¹⁹ G⁵ W¹⁷ 3212 R²⁷ G⁵ W¹⁷ 3213 R²⁸ G⁵ W¹⁷ 3214 R³³ G⁵ W¹⁷ 3215 R³⁸ G⁵ W¹⁷ 3216 R³⁹ G⁵ W¹⁷ 3217 R⁴¹ G⁵ W¹⁷ 3218 R⁴⁶ G⁵ W¹⁷ 3219 R⁴⁷ G⁵ W¹⁷ 3220 R⁴⁹ G⁵ W¹⁷ 3221 R¹ G⁶ W¹⁷ 3222 R² G⁶ W¹⁷ 3223 R⁴ G⁶ W¹⁷ 3224 R⁵ G⁶ W¹⁷ 3225 R⁷ G⁶ W¹⁷ 3226 R⁸ G⁶ W¹⁷ 3227 R¹⁰ G⁶ W¹⁷ 3228 R¹² G⁶ W¹⁷ 3229 R¹⁴ G⁶ W¹⁷ 3230 R¹⁵ G⁶ W¹⁷ 3231 R¹⁹ G⁶ W¹⁷ 3232 R²⁷ G⁶ W¹⁷ 3233 R²⁸ G⁶ W¹⁷ 3234 R³³ G⁶ W¹⁷ 3235 R³⁸ G⁶ W¹⁷ 3236 R³⁹ G⁶ W¹⁷ 3237 R⁴¹ G⁶ W¹⁷ 3238 R⁴⁶ G⁶ W¹⁷ 3239 R⁴⁷ G⁶ W¹⁷ 3240 R⁴⁹ G⁶ W¹⁷ 3241 R¹ G⁹ W¹⁷ 3242 R² G⁹ W¹⁷ 3243 R⁴ G⁹ W¹⁷ 3244 R⁵ G⁹ W¹⁷ 3245 R⁷ G⁹ W¹⁷ 3246 R⁸ G⁹ W¹⁷ 3247 R¹⁰ G⁹ W¹⁷ 3248 R¹² G⁹ W¹⁷ 3249 R¹⁴ G⁹ W¹⁷ 3250 R¹⁵ G⁹ W¹⁷ 3251 R¹⁹ G⁹ W¹⁷ 3252 R²⁷ G⁹ W¹⁷ 3253 R²⁸ G⁹ W¹⁷ 3254 R³³ G⁹ W¹⁷ 3255 R³⁸ G⁹ W¹⁷ 3256 R³⁹ G⁹ W¹⁷ 3257 R⁴¹ G⁹ W¹⁷ 3258 R⁴⁶ G⁹ W¹⁷ 3259 R⁴⁷ G⁹ W¹⁷ 3260 R⁴⁹ G⁹ W¹⁷ 3261 R¹ G¹⁰ W¹⁷ 3262 R² G¹⁰ W¹⁷ 3263 R⁴ G¹⁰ W¹⁷ 3264 R⁵ G¹⁰ W¹⁷ 3265 R⁷ G¹⁰ W¹⁷ 3266 R⁸ G¹⁰ W¹⁷ 3267 R¹⁰ G¹⁰ W¹⁷ 3268 R¹² G¹⁰ W¹⁷ 3269 R¹⁴ G¹⁰ W¹⁷ 3270 R¹⁵ G¹⁰ W¹⁷ 3271 R¹⁹ G¹⁰ W¹⁷ 3272 R²⁷ G¹⁰ W¹⁷ 3273 R²⁸ G¹⁰ W¹⁷ 3274 R³³ G¹⁰ W¹⁷ 3275 R³⁸ G¹⁰ W¹⁷ 3276 R³⁹ G¹⁰ W¹⁷ 3277 R⁴¹ G¹⁰ W¹⁷ 3278 R⁴⁶ G¹⁰ W¹⁷ 3279 R⁴⁷ G¹⁰ W¹⁷ 3280 R⁴⁹ G¹⁰ W¹⁷ 3281 R¹ G²⁵ W¹⁷ 3282 R² G²⁵ W¹⁷ 3283 R⁴ G²⁵ W¹⁷ 3284 R⁵ G²⁵ W¹⁷ 3285 R⁷ G²⁵ W¹⁷ 3286 R⁸ G²⁵ W¹⁷ 3287 R¹⁰ G²⁵ W¹⁷ 3288 R¹² G²⁵ W¹⁷ 3289 R¹⁴ G²⁵ W¹⁷ 3290 R¹⁵ G²⁵ W¹⁷ 3291 R¹⁹ G²⁵ W¹⁷ 3292 R²⁷ G²⁵ W¹⁷ 3293 R²⁸ G²⁵ W¹⁷ 3294 R³³ G²⁵ W¹⁷ 3295 R³⁸ G²⁵ W¹⁷ 3296 R³⁹ G²⁵ W¹⁷ 3297 R⁴¹ G²⁵ W¹⁷ 3298 R⁴⁶ G²⁵ W¹⁷ 3299 R⁴⁷ G²⁵ W¹⁷ 3300 R⁴⁹ G²⁵ W¹⁷ 3301 R¹ G²⁶ W¹⁷ 3302 R² G²⁶ W¹⁷ 3303 R⁴ G²⁶ W¹⁷ 3304 R⁵ G²⁶ W¹⁷ 3305 R⁷ G²⁶ W¹⁷ 3306 R⁸ G²⁶ W¹⁷ 3307 R¹⁰ G²⁶ W¹⁷ 3308 R¹² G²⁶ W¹⁷ 3309 R¹⁴ G²⁶ W¹⁷ 3310 R¹⁵ G²⁶ W¹⁷ 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W²⁸ 3682 R² G²⁵ W²⁸ 3683 R⁴ G²⁵ W²⁸ 3684 R⁵ G²⁵ W²⁸ 3685 R⁷ G²⁵ W²⁸ 3686 R⁸ G²⁵ W²⁸ 3687 R¹⁰ G²⁵ W²⁸ 3688 R¹² G²⁵ W²⁸ 3689 R¹⁴ G²⁵ W²⁸ 3690 R¹⁵ G²⁵ W²⁸ 3691 R¹⁹ G²⁵ W²⁸ 3692 R²⁷ G²⁵ W²⁸ 3693 R²⁸ G²⁵ W²⁸ 3694 R³³ G²⁵ W²⁸ 3695 R³⁸ G²⁵ W²⁸ 3696 R³⁹ G²⁵ W²⁸ 3697 R⁴¹ G²⁵ W²⁸ 3698 R⁴⁶ G²⁵ W²⁸ 3699 R⁴⁷ G²⁵ W²⁸ 3700 R⁴⁹ G²⁵ W²⁸ 3701 R¹ G²⁶ W²⁸ 3702 R² G²⁶ W²⁸ 3703 R⁴ G²⁶ W²⁸ 3704 R⁵ G²⁶ W²⁸ 3705 R⁷ G²⁶ W²⁸ 3706 R⁸ G²⁶ W²⁸ 3707 R¹⁰ G²⁶ W²⁸ 3708 R¹² G²⁶ W²⁸ 3709 R¹⁴ G²⁶ W²⁸ 3710 R¹⁵ G²⁶ W²⁸ 3711 R¹⁹ G²⁶ W²⁸ 3712 R²⁷ G²⁶ W²⁸ 3713 R²⁸ G²⁶ W²⁸ 3714 R³³ G²⁶ W²⁸ 3715 R³⁸ G²⁶ W²⁸ 3716 R³⁹ G²⁶ W²⁸ 3717 R⁴¹ G²⁶ W²⁸ 3718 R⁴⁶ G²⁶ W²⁸ 3719 R⁴⁷ G²⁶ W²⁸ 3720 R⁴⁹ G²⁶ W²⁸ 3721 R¹ G²⁷ W²⁸ 3722 R² G²⁷ W²⁸ 3723 R⁴ G²⁷ W²⁸ 3724 R⁵ G²⁷ W²⁸ 3725 R⁷ G²⁷ W²⁸ 3726 R⁸ G²⁷ W²⁸ 3727 R¹⁰ G²⁷ W²⁸ 3728 R¹² G²⁷ W²⁸ 3729 R¹⁴ G²⁷ W²⁸ 3730 R¹⁵ G²⁷ W²⁸ 3731 R¹⁹ G²⁷ W²⁸ 3732 R²⁷ G²⁷ W²⁸ 3733 R²⁸ G²⁷ W²⁸ 3734 R³³ G²⁷ W²⁸ 3735 R³⁸ G²⁷ W²⁸ 3736 R³⁹ G²⁷ W²⁸ 3737 R⁴¹ G²⁷ W²⁸ 3738 R⁴⁶ G²⁷ W²⁸ 3739 R⁴⁷ G²⁷ W²⁸ 3740 R⁴⁹ G²⁷ W²⁸ 3741 R¹ G²⁸ W²⁸ 3742 R² G²⁸ W²⁸ 3743 R⁴ G²⁸ W²⁸ 3744 R⁵ G²⁸ W²⁸ 3745 R⁷ G²⁸ W²⁸ 3746 R⁸ G²⁸ W²⁸ 3747 R¹⁰ G²⁸ W²⁸ 3748 R¹² G²⁸ W²⁸ 3749 R¹⁴ G²⁸ W²⁸ 3750 R¹⁵ G²⁸ W²⁸ 3751 R¹⁹ G²⁸ W²⁸ 3752 R²⁷ G²⁸ W²⁸ 3753 R²⁸ G²⁸ W²⁸ 3754 R³³ G²⁸ W²⁸ 3755 R³⁸ G²⁸ W²⁸ 3756 R³⁹ G²⁸ W²⁸ 3757 R⁴¹ G²⁸ W²⁸ 3758 R⁴⁶ G²⁸ W²⁸ 3759 R⁴⁷ G²⁸ W²⁸ 3760 R⁴⁹ G²⁸ W²⁸ 3761 R¹ G¹ W³⁶ 3762 R² G¹ W³⁶ 3763 R⁴ G¹ W³⁶ 3764 R⁵ G¹ W³⁶ 3765 R⁷ G¹ W³⁶ 3766 R⁸ G¹ W³⁶ 3767 R¹⁰ G¹ W³⁶ 3768 R¹² G¹ W³⁶ 3769 R¹⁴ G¹ W³⁶ 3770 R¹⁵ G¹ W³⁶ 3771 R¹⁹ G¹ W³⁶ 3772 R²⁷ G¹ W³⁶ 3773 R²⁸ G¹ W³⁶ 3774 R³³ G¹ W³⁶ 3775 R³⁸ G¹ W³⁶ 3776 R³⁹ G¹ W³⁶ 3777 R⁴¹ G¹ W³⁶ 3778 R⁴⁶ G¹ W³⁶ 3779 R⁴⁷ G¹ W³⁶ 3780 R⁴⁹ G¹ W³⁶ 3781 R¹ G³ W³⁶ 3782 R² G³ W³⁶ 3783 R⁴ G³ W³⁶ 3784 R⁵ G³ W³⁶ 3785 R⁷ G³ W³⁶ 3786 R⁸ G³ W³⁶ 3787 R¹⁰ G³ W³⁶ 3788 R¹² G³ W³⁶ 3789 R¹⁴ G³ W³⁶ 3790 R¹⁵ G³ W³⁶ 3791 R¹⁹ G³ W³⁶ 3792 R²⁷ G³ W³⁶ 3793 R²⁸ G³ W³⁶ 3794 R³³ G³ W³⁶ 3795 R³⁸ G³ W³⁶ 3796 R³⁹ G³ W³⁶ 3797 R⁴¹ G³ W³⁶ 3798 R⁴⁶ G³ W³⁶ 3799 R⁴⁷ G³ W³⁶ 3800 R⁴⁹ G³ W³⁶ 3801 R¹ G⁵ W³⁶ 3802 R² G⁵ W³⁶ 3803 R⁴ G⁵ W³⁶ 3804 R⁵ G⁵ W³⁶ 3805 R⁷ G⁵ W³⁶ 3806 R⁸ G⁵ W³⁶ 3807 R¹⁰ G⁵ W³⁶ 3808 R¹² G⁵ W³⁶ 3809 R¹⁴ G⁵ W³⁶ 3810 R¹⁵ G⁵ W³⁶ 3811 R¹⁹ G⁵ W³⁶ 3812 R²⁷ G⁵ W³⁶ 3813 R²⁸ G⁵ W³⁶ 3814 R³³ G⁵ W³⁶ 3815 R³⁸ G⁵ W³⁶ 3816 R³⁹ G⁵ W³⁶ 3817 R⁴¹ G⁵ W³⁶ 3818 R⁴⁶ G⁵ W³⁶ 3819 R⁴⁷ G⁵ W³⁶ 3820 R⁴⁹ G⁵ W³⁶ 3821 R¹ G⁶ W³⁶ 3822 R² G⁶ W³⁶ 3823 R⁴ G⁶ W³⁶ 3824 R⁵ G⁶ W³⁶ 3825 R⁷ G⁶ W³⁶ 3826 R⁸ G⁶ W³⁶ 3827 R¹⁰ G⁶ W³⁶ 3828 R¹² G⁶ W³⁶ 3829 R¹⁴ G⁶ W³⁶ 3830 R¹⁵ G⁶ W³⁶ 3831 R¹⁹ G⁶ W³⁶ 3832 R²⁷ G⁶ W³⁶ 3833 R²⁸ G⁶ W³⁶ 3834 R³³ G⁶ W³⁶ 3835 R³⁸ G⁶ W³⁶ 3836 R³⁹ G⁶ W³⁶ 3837 R⁴¹ G⁶ W³⁶ 3838 R⁴⁶ G⁶ W³⁶ 3839 R⁴⁷ G⁶ W³⁶ 3840 R⁴⁹ G⁶ W³⁶ 3841 R¹ G⁹ W³⁶ 3842 R² G⁹ W³⁶ 3843 R⁴ G⁹ W³⁶ 3844 R⁵ G⁹ W³⁶ 3845 R⁷ G⁹ W³⁶ 3846 R⁸ G⁹ W³⁶ 3847 R¹⁰ G⁹ W³⁶ 3848 R¹² G⁹ W³⁶ 3849 R¹⁴ G⁹ W³⁶ 3850 R¹⁵ G⁹ W³⁶ 3851 R¹⁹ G⁹ W³⁶ 3852 R²⁷ G⁹ W³⁶ 3853 R²⁸ G⁹ W³⁶ 3854 R³³ G⁹ W³⁶ 3855 R³⁸ G⁹ W³⁶ 3856 R³⁹ G⁹ W³⁶ 3857 R⁴¹ G⁹ W³⁶ 3858 R⁴⁶ G⁹ W³⁶ 3859 R⁴⁷ G⁹ W³⁶ 3860 R⁴⁹ G⁹ W³⁶ 3861 R¹ G¹⁰ W³⁶ 3862 R² G¹⁰ W³⁶ 3863 R⁴ G¹⁰ W³⁶ 3864 R⁵ G¹⁰ W³⁶ 3865 R⁷ G¹⁰ W³⁶ 3866 R⁸ G¹⁰ W³⁶ 3867 R¹⁰ G¹⁰ W³⁶ 3868 R¹² G¹⁰ W³⁶ 3869 R¹⁴ G¹⁰ W³⁶ 3870 R¹⁵ G¹⁰ W³⁶ 3871 R¹⁹ G¹⁰ W³⁶ 3872 R²⁷ G¹⁰ W³⁶ 3873 R²⁸ G¹⁰ W³⁶ 3874 R³³ G¹⁰ W³⁶ 3875 R³⁸ G¹⁰ W³⁶ 3876 R³⁹ G¹⁰ W³⁶ 3877 R⁴¹ G¹⁰ W³⁶ 3878 R⁴⁶ G¹⁰ W³⁶ 3879 R⁴⁷ G¹⁰ W³⁶ 3880 R⁴⁹ G¹⁰ W³⁶ 3881 R¹ G²⁵ W³⁶ 3882 R² G²⁵ W³⁶ 3883 R⁴ G²⁵ W³⁶ 3884 R⁵ G²⁵ W³⁶ 3885 R⁷ G²⁵ W³⁶ 3886 R⁸ G²⁵ W³⁶ 3887 R¹⁰ G²⁵ W³⁶ 3888 R¹² G²⁵ W³⁶ 3889 R¹⁴ G²⁵ W³⁶ 3890 R¹⁵ G²⁵ W³⁶ 3891 R¹⁹ G²⁵ W³⁶ 3892 R²⁷ G²⁵ W³⁶ 3893 R²⁸ G²⁵ W³⁶ 3894 R³³ G²⁵ W³⁶ 3895 R³⁸ G²⁵ W³⁶ 3896 R³⁹ G²⁵ W³⁶ 3897 R⁴¹ G²⁵ W³⁶ 3898 R⁴⁶ G²⁵ W³⁶ 3899 R⁴⁷ G²⁵ W³⁶ 3900 R⁴⁹ G²⁵ W³⁶ 3901 R¹ G²⁶ W³⁶ 3902 R² G²⁶ W³⁶ 3903 R⁴ G²⁶ W³⁶ 3904 R⁵ G²⁶ W³⁶ 3905 R⁷ G²⁶ W³⁶ 3906 R⁸ G²⁶ W³⁶ 3907 R¹⁰ G²⁶ W³⁶ 3908 R¹² G²⁶ W³⁶ 3909 R¹⁴ G²⁶ W³⁶ 3910 R¹⁵ G²⁶ W³⁶ 3911 R¹⁹ G²⁶ W³⁶ 3912 R²⁷ G²⁶ W³⁶ 3913 R²⁸ G²⁶ W³⁶ 3914 R³³ G²⁶ W³⁶ 3915 R³⁸ G²⁶ W³⁶ 3916 R³⁹ G²⁶ W³⁶ 3917 R⁴¹ G²⁶ W³⁶ 3918 R⁴⁶ G²⁶ W³⁶ 3919 R⁴⁷ G²⁶ W³⁶ 3920 R⁴⁹ G²⁶ W³⁶ 3921 R¹ G²⁷ W³⁶ 3922 R² G²⁷ W³⁶ 3923 R⁴ G²⁷ W³⁶ 3924 R⁵ G²⁷ W³⁶ 3925 R⁷ G²⁷ W³⁶ 3926 R⁸ G²⁷ W³⁶ 3927 R¹⁰ G²⁷ W³⁶ 3928 R¹² G²⁷ W³⁶ 3929 R¹⁴ G²⁷ W³⁶ 3930 R¹⁵ G²⁷ W³⁶ 3931 R¹⁹ G²⁷ W³⁶ 3932 R²⁷ G²⁷ W³⁶ 3933 R²⁸ G²⁷ W³⁶ 3934 R³³ G²⁷ W³⁶ 3935 R³⁸ G²⁷ W³⁶ 3936 R³⁹ G²⁷ W³⁶ 3937 R⁴¹ G²⁷ W³⁶ 3938 R⁴⁶ G²⁷ W³⁶ 3939 R⁴⁷ G²⁷ W³⁶ 3940 R⁴⁹ G²⁷ W³⁶ 3941 R¹ G²⁸ W³⁶ 3942 R² G²⁸ W³⁶ 3943 R⁴ G²⁸ W³⁶ 3944 R⁵ G²⁸ W³⁶ 3945 R⁷ G²⁸ W³⁶ 3946 R⁸ G²⁸ W³⁶ 3947 R¹⁰ G²⁸ W³⁶ 3948 R¹² G²⁸ W³⁶ 3949 R¹⁴ G²⁸ W³⁶ 3950 R¹⁵ G²⁸ W³⁶ 3951 R¹⁹ G²⁸ W³⁶ 3952 R²⁷ G²⁸ W³⁶ 3953 R²⁸ G²⁸ W³⁶ 3954 R³³ G²⁸ W³⁶ 3955 R³⁸ G²⁸ W³⁶ 3956 R³⁹ G²⁸ W³⁶ 3957 R⁴¹ G²⁸ W³⁶ 3958 R⁴⁶ G²⁸ W³⁶ 3959 R⁴⁷ G²⁸ W³⁶ 3960 R⁴⁹ G²⁸ W³⁶ 3961 R¹ G¹ W³⁷ 3962 R² G¹ W³⁷ 3963 R⁴ G¹ W³⁷ 3964 R⁵ G¹ W³⁷ 3965 R⁷ G¹ W³⁷ 3966 R⁸ G¹ W³⁷ 3967 R¹⁰ G¹ W³⁷ 3968 R¹² G¹ W³⁷ 3969 R¹⁴ G¹ W³⁷ 3970 R¹⁵ G¹ W³⁷ 3971 R¹⁹ G¹ W³⁷ 3972 R²⁷ G¹ W³⁷ 3973 R²⁸ G¹ W³⁷ 3974 R³³ G¹ W³⁷ 3975 R³⁸ G¹ W³⁷ 3976 R³⁹ G¹ W³⁷ 3977 R⁴¹ G¹ W³⁷ 3978 R⁴⁶ G¹ W³⁷ 3979 R⁴⁷ G¹ W³⁷ 3980 R⁴⁹ G¹ W³⁷ 3981 R¹ G³ W³⁷ 3982 R² G³ W³⁷ 3983 R⁴ G³ W³⁷ 3984 R⁵ G³ W³⁷ 3985 R⁷ G³ W³⁷ 3986 R⁸ G³ W³⁷ 3987 R¹⁰ G³ W³⁷ 3988 R¹² G³ W³⁷ 3989 R¹⁴ G³ W³⁷ 3990 R¹⁵ G³ W³⁷ 3991 R¹⁹ G³ W³⁷ 3992 R²⁷ G³ W³⁷ 3993 R²⁸ G³ W³⁷ 3994 R³³ G³ W³⁷ 3995 R³⁸ G³ W³⁷ 3996 R³⁹ G³ W³⁷ 3997 R⁴¹ G³ W³⁷ 3998 R⁴⁶ G³ W³⁷ 3999 R⁴⁷ G³ W³⁷ 4000 R⁴⁹ G³ W³⁷ 4001 R¹ G⁵ W³⁷ 4002 R² G⁵ W³⁷ 4003 R⁴ G⁵ W³⁷ 4004 R⁵ G⁵ W³⁷ 4005 R⁷ G⁵ W³⁷ 4006 R⁸ G⁵ W³⁷ 4007 R¹⁰ G⁵ W³⁷ 4008 R¹² G⁵ W³⁷ 4009 R¹⁴ G⁵ W³⁷ 4010 R¹⁵ G⁵ W³⁷ 4011 R¹⁹ G⁵ W³⁷ 4012 R²⁷ G⁵ W³⁷ 4013 R²⁸ G⁵ W³⁷ 4014 R³³ G⁵ W³⁷ 4015 R³⁸ G⁵ W³⁷ 4016 R³⁹ G⁵ W³⁷ 4017 R⁴¹ G⁵ W³⁷ 4018 R⁴⁶ G⁵ W³⁷ 4019 R⁴⁷ G⁵ W³⁷ 4020 R⁴⁹ G⁵ W³⁷ 4021 R¹ G⁶ W³⁷ 4022 R² G⁶ W³⁷ 4023 R⁴ G⁶ W³⁷ 4024 R⁵ G⁶ W³⁷ 4025 R⁷ G⁶ W³⁷ 4026 R⁸ G⁶ W³⁷ 4027 R¹⁰ G⁶ W³⁷ 4028 R¹² G⁶ W³⁷ 4029 R¹⁴ G⁶ W³⁷ 4030 R¹⁵ G⁶ W³⁷ 4031 R¹⁹ G⁶ W³⁷ 4032 R²⁷ G⁶ W³⁷ 4033 R²⁸ G⁶ W³⁷ 4034 R³³ G⁶ W³⁷ 4035 R³⁸ G⁶ W³⁷ 4036 R³⁹ G⁶ W³⁷ 4037 R⁴¹ G⁶ W³⁷ 4038 R⁴⁶ G⁶ W³⁷ 4039 R⁴⁷ G⁶ W³⁷ 4040 R⁴⁹ G⁶ W³⁷ 4041 R¹ G⁹ W³⁷ 4042 R² G⁹ W³⁷ 4043 R⁴ G⁹ W³⁷ 4044 R⁵ G⁹ W³⁷ 4045 R⁷ G⁹ W³⁷ 4046 R⁸ G⁹ W³⁷ 4047 R¹⁰ G⁹ W³⁷ 4048 R¹² G⁹ W³⁷ 4049 R¹⁴ G⁹ W³⁷ 4050 R¹⁵ G⁹ W³⁷ 4051 R¹⁹ G⁹ W³⁷ 4052 R²⁷ G⁹ W³⁷ 4053 R²⁸ G⁹ W³⁷ 4054 R³³ G⁹ W³⁷ 4055 R³⁸ G⁹ W³⁷ 4056 R³⁹ G⁹ W³⁷ 4057 R⁴¹ G⁹ W³⁷ 4058 R⁴⁶ G⁹ W³⁷ 4059 R⁴⁷ G⁹ W³⁷ 4060 R⁴⁹ G⁹ W³⁷ 4061 R¹ G¹⁰ W³⁷ 4062 R² G¹⁰ W³⁷ 4063 R⁴ G¹⁰ W³⁷ 4064 R⁵ G¹⁰ W³⁷ 4065 R⁷ G¹⁰ W³⁷ 4066 R⁸ G¹⁰ W³⁷ 4067 R¹⁰ G¹⁰ W³⁷ 4068 R¹² G¹⁰ W³⁷ 4069 R¹⁴ G¹⁰ W³⁷ 4070 R¹⁵ G¹⁰ W³⁷ 4071 R¹⁹ G¹⁰ W³⁷ 4072 R²⁷ G¹⁰ W³⁷ 4073 R²⁸ G¹⁰ W³⁷ 4074 R³³ G¹⁰ W³⁷ 4075 R³⁸ G¹⁰ W³⁷ 4076 R³⁹ G¹⁰ W³⁷ 4077 R⁴¹ G¹⁰ W³⁷ 4078 R⁴⁶ G¹⁰ W³⁷ 4079 R⁴⁷ G¹⁰ W³⁷ 4080 R⁴⁹ G¹⁰ W³⁷ 4081 R¹ G²⁵ W³⁷ 4082 R² G²⁵ W³⁷ 4083 R⁴ G²⁵ W³⁷ 4084 R⁵ G²⁵ W³⁷ 4085 R⁷ G²⁵ W³⁷ 4086 R⁸ G²⁵ W³⁷ 4087 R¹⁰ G²⁵ W³⁷ 4088 R¹² G²⁵ W³⁷ 4089 R¹⁴ G²⁵ W³⁷ 4090 R¹⁵ G²⁵ W³⁷ 4091 R¹⁹ G²⁵ W³⁷ 4092 R²⁷ G²⁵ W³⁷ 4093 R²⁸ G²⁵ W³⁷ 4094 R³³ G²⁵ W³⁷ 4095 R³⁸ G²⁵ W³⁷ 4096 R³⁹ G²⁵ W³⁷ 4097 R⁴¹ G²⁵ W³⁷ 4098 R⁴⁶ G²⁵ W³⁷ 4099 R⁴⁷ G²⁵ W³⁷ 4100 R⁴⁹ G²⁵ W³⁷ 4101 R¹ G²⁶ W³⁷ 4102 R² G²⁶ W³⁷ 4103 R⁴ G²⁶ W³⁷ 4104 R⁵ G²⁶ W³⁷ 4105 R⁷ G²⁶ W³⁷ 4106 R⁸ G²⁶ W³⁷ 4107 R¹⁰ G²⁶ W³⁷ 4108 R¹² G²⁶ W³⁷ 4109 R¹⁴ G²⁶ W³⁷ 4110 R¹⁵ G²⁶ W³⁷ 4111 R¹⁹ G²⁶ W³⁷ 4112 R²⁷ G²⁶ W³⁷ 4113 R²⁸ G²⁶ W³⁷ 4114 R³³ G²⁶ W³⁷ 4115 R³⁸ G²⁶ W³⁷ 4116 R³⁹ G²⁶ W³⁷ 4117 R⁴¹ G²⁶ W³⁷ 4118 R⁴⁶ G²⁶ W³⁷ 4119 R⁴⁷ G²⁶ W³⁷ 4120 R⁴⁹ G²⁶ W³⁷ 4121 R¹ G²⁷ W³⁷ 4122 R² G²⁷ W³⁷ 4123 R⁴ G²⁷ W³⁷ 4124 R⁵ G²⁷ W³⁷ 4125 R⁷ G²⁷ W³⁷ 4126 R⁸ G²⁷ W³⁷ 4127 R¹⁰ G²⁷ W³⁷ 4128 R¹² G²⁷ W³⁷ 4129 R¹⁴ G²⁷ W³⁷ 4130 R¹⁵ G²⁷ W³⁷ 4131 R¹⁹ G²⁷ W³⁷ 4132 R²⁷ G²⁷ W³⁷ 4133 R²⁸ G²⁷ W³⁷ 4134 R³³ G²⁷ W³⁷ 4135 R³⁸ G²⁷ W³⁷ 4136 R³⁹ G²⁷ W³⁷ 4137 R⁴¹ G²⁷ W³⁷ 4138 R⁴⁶ G²⁷ W³⁷ 4139 R⁴⁷ G²⁷ W³⁷ 4140 R⁴⁹ G²⁷ W³⁷ 4141 R¹ G²⁸ W³⁷ 4142 R² G²⁸ W³⁷ 4143 R⁴ G²⁸ W³⁷ 4144 R⁵ G²⁸ W³⁷ 4145 R⁷ G²⁸ W³⁷ 4146 R⁸ G²⁸ W³⁷ 4147 R¹⁰ G²⁸ W³⁷ 4148 R¹² G²⁸ W³⁷ 4149 R¹⁴ G²⁸ W³⁷ 4150 R¹⁵ G²⁸ W³⁷ 4151 R¹⁹ G²⁸ W³⁷ 4152 R²⁷ G²⁸ W³⁷ 4153 R²⁸ G²⁸ W³⁷ 4154 R³³ G²⁸ W³⁷ 4155 R³⁸ G²⁸ W³⁷ 4156 R³⁹ G²⁸ W³⁷ 4157 R⁴¹ G²⁸ W³⁷ 4158 R⁴⁶ G²⁸ W³⁷ 4159 R⁴⁷ G²⁸ W³⁷ 4160 R⁴⁹ G²⁸ W³⁷ 4161 R¹ G⁷ W¹ 4162 R² G⁷ W¹ 4163 R⁴ G⁷ W¹ 4164 R⁵ G⁷ W¹ 4165 R⁷ G⁷ W¹ 4166 R⁸ G⁷ W¹ 4167 R¹⁰ G⁷ W¹ 4168 R¹² G⁷ W¹ 4169 R¹⁴ G⁷ W¹ 4170 R¹⁵ G⁷ W¹ 4171 R¹⁹ G⁷ W¹ 4172 R²⁷ G⁷ W¹ 4173 R²⁸ G⁷ W¹ 4174 R³³ G⁷ W¹ 4175 R³⁸ G⁷ W¹ 4176 R³⁹ G⁷ W¹ 4177 R⁴¹ G⁷ W¹ 4178 R⁴⁶ G⁷ W¹ 4179 R⁴⁷ G⁷ W¹ 4180 R⁴⁹ G⁷ W¹ 4181 R¹ G⁸ W¹ 4182 R² G⁸ W¹ 4183 R⁴ G⁸ W¹ 4184 R⁵ G⁸ W¹ 4185 R⁷ G⁸ W¹ 4186 R⁸ G⁸ W¹ 4187 R¹⁰ G⁸ W¹ 4188 R¹² G⁸ W¹ 4189 R¹⁴ G⁸ W¹ 4190 R¹⁵ G⁸ W¹ 4191 R¹⁹ G⁸ W¹ 4192 R²⁷ G⁸ W¹ 4193 R²⁸ G⁸ W¹ 4194 R³³ G⁸ W¹ 4195 R³⁸ G⁸ W¹ 4196 R³⁹ G⁸ W¹ 4197 R⁴¹ G⁸ W¹ 4198 R⁴⁶ G⁸ W¹ 4199 R⁴⁷ G⁸ W¹ 4200 R⁴⁹ G⁸ W¹ 4201 R¹ G⁷ W¹¹ 4202 R² G⁷ W¹¹ 4203 R⁴ G⁷ W¹¹ 4204 R⁵ G⁷ W¹¹ 4205 R⁷ G⁷ W¹¹ 4206 R⁸ G⁷ W¹¹ 4207 R¹⁰ G⁷ W¹¹ 4208 R¹² G⁷ W¹¹ 4209 R¹⁴ G⁷ W¹¹ 4210 R¹⁵ G⁷ W¹¹ 4211 R¹⁹ G⁷ W¹¹ 4212 R²⁷ G⁷ W¹¹ 4213 R²⁸ G⁷ W¹¹ 4214 R³³ G⁷ W¹¹ 4215 R³⁸ G⁷ W¹¹ 4216 R³⁹ G⁷ W¹¹ 4217 R⁴¹ G⁷ W¹¹ 4218 R⁴⁶ G⁷ W¹¹ 4219 R⁴⁷ G⁷ W¹¹ 4220 R⁴⁹ G⁷ W¹¹ 4221 R¹ G⁸ W¹¹ 4222 R² G⁸ W¹¹ 4223 R⁴ G⁸ W¹¹ 4224 R⁵ G⁸ W¹¹ 4225 R⁷ G⁸ W¹¹ 4226 R⁸ G⁸ W¹¹ 4227 R¹⁰ G⁸ W¹¹ 4228 R¹² G⁸ W¹¹ 4229 R¹⁴ G⁸ W¹¹ 4230 R¹⁵ G⁸ W¹¹ 4231 R¹⁹ G⁸ W¹¹ 4232 R²⁷ G⁸ W¹¹ 4233 R²⁸ G⁸ W¹¹ 4234 R³³ G⁸ W¹¹ 4235 R³⁸ G⁸ W¹¹ 4236 R³⁹ G⁸ W¹¹ 4237 R⁴¹ G⁸ W¹¹ 4238 R⁴⁶ G⁸ W¹¹ 4239 R⁴⁷ G⁸ W¹¹ 4240 R⁴⁹ G⁸ W¹¹ 4241 R⁴ G² W³ 4242 R⁴ G² W⁴ 4243 R⁴ G² W⁷ 4244 R⁴ G² W⁸ 4245 R⁴ G² W⁹ 4246 R⁴ G² W¹⁰ 4247 R⁴ G² W¹² 4248 R⁴ G² W¹³ 4249 R⁴ G² W¹⁴ 4250 R⁴ G² W¹⁵ 4251 R⁴ G² W¹⁶ 4252 R⁴ G² W¹⁸ 4253 R⁴ G² W¹⁹ 4254 R⁴ G² W²⁰ 4255 R⁴ G² W²² 4256 R⁴ G² W²³ 4257 R⁴ G² W²⁴ 4258 R⁴ G² W²⁵ 4259 R⁴ G² W²⁶ 4260 R⁴ G² W²⁷ 4261 R⁴ G² W²⁹ 4262 R⁴ G² W³⁰ 4263 R⁴ G² W³¹ 4264 R⁴ G² W³² 4265 R⁴ G² W³³ 4266 R⁴ G² W³⁴ 4267 R⁴ G² W³⁵ 4268 R⁴ G² W³⁸ 4269 R⁴ G² W³⁹ 4270 R⁴ G² W⁴⁰ 4271 R⁸ G² W³ 4272 R⁸ G² W⁴ 4273 R⁸ G² W⁷ 4274 R⁸ G² W⁸ 4275 R⁸ G² W⁹ 4276 R⁸ G² W¹⁰ 4277 R⁸ G² W¹² 4278 R⁸ G² W¹³ 4279 R⁸ G² W¹⁴ 4280 R⁸ G² W¹⁵ 4281 R⁸ G² W¹⁶ 4282 R⁸ G² W¹⁸ 4283 R⁸ G² W¹⁹ 4284 R⁸ G² W²⁰ 4285 R⁸ G² W²² 4286 R⁸ G² W²³ 4287 R⁸ G² W²⁴ 4288 R⁸ G² W²⁵ 4289 R⁸ G² W²⁶ 4290 R⁸ G² W²⁷ 4291 R⁸ G² W²⁹ 4292 R⁸ G² W³⁰ 4293 R⁸ G² W³¹ 4294 R⁸ G² W³² 4295 R⁸ G² W³³ 4296 R⁸ G² W³⁴ 4297 R⁸ G² W³⁵ 4298 R⁸ G² W³⁸ 4299 R⁸ G² W³⁹ 4300 R⁸ G² W⁴⁰ 4301 R¹⁹ G² W³ 4302 R¹⁹ G² W⁴ 4303 R¹⁹ G² W⁷ 4304 R¹⁹ G² W⁸ 4305 R¹⁹ G² W⁹ 4306 R¹⁹ G² W¹⁰ 4307 R¹⁹ G² W¹² 4308 R¹⁹ G² W¹³ 4309 R¹⁹ G² W¹⁴ 4310 R¹⁹ G² W¹⁵ 4311 R¹⁹ G² W¹⁶ 4312 R¹⁹ G² W¹⁸ 4313 R¹⁹ G² W¹⁹ 4314 R¹⁹ G² W²⁰ 4315 R¹⁹ G² W²² 4316 R¹⁹ G² W²³ 4317 R¹⁹ G² W²⁴ 4318 R¹⁹ G² W²⁵ 4319 R¹⁹ G² W²⁶ 4320 R¹⁹ G² W²⁷ 4321 R¹⁹ G² W²⁹ 4322 R¹⁹ G² W³⁰ 4323 R¹⁹ G² W³¹ 4324 R¹⁹ G² W³² 4325 R¹⁹ G² W³³ 4326 R¹⁹ G² W³⁴ 4327 R¹⁹ G² W³⁵ 4328 R¹⁹ G² W³⁸ 4329 R¹⁹ G² W³⁹ 4330 R¹⁹ G² W⁴⁰ 4331 R⁴ G⁴ W³ 4332 R⁴ G⁴ W⁴ 4333 R⁴ G⁴ W⁷ 4334 R⁴ G⁴ W⁸ 4335 R⁴ G⁴ W⁹ 4336 R⁴ G⁴ W¹⁰ 4337 R⁴ G⁴ W¹² 4338 R⁴ G⁴ W¹³ 4339 R⁴ G⁴ W¹⁴ 4340 R⁴ G⁴ W¹⁵ 4341 R⁴ G⁴ W¹⁶ 4342 R⁴ G⁴ W¹⁸ 4343 R⁴ G⁴ W¹⁹ 4344 R⁴ G⁴ W²⁰ 4345 R⁴ G⁴ W²² 4346 R⁴ G⁴ W²³ 4347 R⁴ G⁴ W²⁴ 4348 R⁴ G⁴ W²⁵ 4349 R⁴ G⁴ W²⁶ 4350 R⁴ G⁴ W²⁷ 4351 R⁴ G⁴ W²⁹ 4352 R⁴ G⁴ W³⁰ 4353 R⁴ G⁴ W³¹ 4354 R⁴ G⁴ W³² 4355 R⁴ G⁴ W³³ 4356 R⁴ G⁴ W³⁴ 4357 R⁴ G⁴ W³⁵ 4358 R⁴ G⁴ W³⁸ 4359 R⁴ G⁴ W³⁹ 4360 R⁴ G⁴ W⁴⁰ 4361 R⁸ G⁴ W³ 4362 R⁸ G⁴ W⁴ 4363 R⁸ G⁴ W⁷ 4364 R⁸ G⁴ W⁸ 4365 R⁸ G⁴ W⁹ 4366 R⁸ G⁴ W¹⁰ 4367 R⁸ G⁴ W¹² 4368 R⁸ G⁴ W¹³ 4369 R⁸ G⁴ W¹⁴ 4370 R⁸ G⁴ W¹⁵ 4371 R⁸ G⁴ W¹⁶ 4372 R⁸ G⁴ W¹⁸ 4373 R⁸ G⁴ W¹⁹ 4374 R⁸ G⁴ W²⁰ 4375 R⁸ G⁴ W²² 4376 R⁸ G⁴ W²³ 4377 R⁸ G⁴ W²⁴ 4378 R⁸ G⁴ W²⁵ 4379 R⁸ G⁴ W²⁶ 4380 R⁸ G⁴ W²⁷ 4381 R⁸ G⁴ W²⁹ 4382 R⁸ G⁴ W³⁰ 4383 R⁸ G⁴ W³¹ 4384 R⁸ G⁴ W³² 4385 R⁸ G⁴ W³³ 4386 R⁸ G⁴ W³⁴ 4387 R⁸ G⁴ W³⁵ 4388 R⁸ G⁴ W³⁸ 4389 R⁸ G⁴ W³⁹ 4390 R⁸ G⁴ W⁴⁰ 4391 R¹⁹ G⁴ W³ 4392 R¹⁹ G⁴ W⁴ 4393 R¹⁹ G⁴ W⁷ 4394 R¹⁹ G⁴ W⁸ 4395 R¹⁹ G⁴ W⁹ 4396 R¹⁹ G⁴ W¹⁰ 4397 R¹⁹ G⁴ W¹² 4398 R¹⁹ G⁴ W¹³ 4399 R¹⁹ G⁴ W¹⁴ 4400 R¹⁹ G⁴ W¹⁵ 4401 R¹⁹ G⁴ W¹⁶ 4402 R¹⁹ G⁴ W¹⁸ 4403 R¹⁹ G⁴ W¹⁹ 4404 R¹⁹ G⁴ W²⁰ 4405 R¹⁹ G⁴ W²² 4406 R¹⁹ G⁴ W²³ 4407 R¹⁹ G⁴ W²⁴ 4408 R¹⁹ G⁴ W²⁵ 4409 R¹⁹ G⁴ W²⁶ 4410 R¹⁹ G⁴ W²⁷ 4411 R¹⁹ G⁴ W²⁹ 4412 R¹⁹ G⁴ W³⁰ 4413 R¹⁹ G⁴ W³¹ 4414 R¹⁹ G⁴ W³² 4415 R¹⁹ G⁴ W³³ 4416 R¹⁹ G⁴ W³⁴ 4417 R¹⁹ G⁴ W³⁵ 4418 R¹⁹ G⁴ W³⁸ 4419 R¹⁹ G⁴ W³⁹ 4420 R¹⁹ G⁴ W⁴⁰ 4421 R¹ G² W⁴² 4422 R² G² W⁴² 4423 R³ G² W⁴² 4424 R⁴ G² W⁴² 4425 R⁵ G² W⁴² 4426 R⁶ G² W⁴² 4427 R⁷ G² W⁴² 4428 R⁸ G² W⁴² 4429 R⁹ G² W⁴² 4430 R¹⁰ G² W⁴² 4431 R¹¹ G² W⁴² 4432 R¹² G² W⁴² 4433 R¹³ G² W⁴² 4434 R¹⁴ G² W⁴² 4435 R¹⁵ G² W⁴² 4436 R¹⁶ G² W⁴² 4437 R¹⁷ G² W⁴² 4438 R¹⁸ G² W⁴² 4439 R¹⁹ G² W⁴² 4440 R²⁰ G² W⁴² 4441 R²¹ G² W⁴² 4442 R²² G² W⁴² 4443 R²³ G² W⁴² 4444 R²⁴ G² W⁴² 4445 R²⁵ G² W⁴² 4446 R²⁶ G² W⁴² 4447 R²⁷ G² W⁴² 4448 R²⁸ G² W⁴² 4449 R²⁹ G² W⁴² 4450 R³⁰ G² W⁴² 4451 R³¹ G² W⁴² 4452 R³² G² W⁴² 4453 R³³ G² W⁴² 4454 R³⁴ G² W⁴² 4455 R³⁵ G² W⁴² 4456 R³⁶ G² W⁴² 4457 R³⁷ G² W⁴² 4458 R³⁸ G² W⁴² 4459 R³⁹ G² W⁴² 4460 R⁴⁰ G² W⁴² 4461 R⁴¹ G² W⁴² 4462 R⁴² G² W⁴² 4463 R⁴³ G² W⁴² 4464 R⁴⁴ G² W⁴² 4465 R⁴⁵ G² W⁴² 4466 R⁴⁶ G² W⁴² 4467 R⁴⁷ G² W⁴² 4468 R⁴⁸ G² W⁴² 4469 R⁴⁹ G² W⁴² 4470 R⁵⁰ G² W⁴² 4471 R¹ G⁴ W⁴² 4472 R² G⁴ W⁴² 4473 R³ G⁴ W⁴² 4474 R⁴ G⁴ W⁴² 4475 R⁵ G⁴ W⁴² 4476 R⁶ G⁴ W⁴² 4477 R⁷ G⁴ W⁴² 4478 R⁸ G⁴ W⁴² 4479 R⁹ G⁴ W⁴² 4480 R¹⁰ G⁴ W⁴² 4481 R¹¹ G⁴ W⁴² 4482 R¹² G⁴ W⁴² 4483 R¹³ G⁴ W⁴² 4484 R¹⁴ G⁴ W⁴² 4485 R¹⁵ G⁴ W⁴² 4486 R¹⁶ G⁴ W⁴² 4487 R¹⁷ G⁴ W⁴² 4488 R¹⁸ G⁴ W⁴² 4489 R¹⁹ G⁴ W⁴² 4490 R²⁰ G⁴ W⁴² 4491 R²¹ G⁴ W⁴² 4492 R²² G⁴ W⁴² 4493 R²³ G⁴ W⁴² 4494 R²⁴ G⁴ W⁴² 4495 R²⁵ G⁴ W⁴² 4496 R²⁶ G⁴ W⁴² 4497 R²⁷ G⁴ W⁴² 4498 R²⁸ G⁴ W⁴² 4499 R²⁹ G⁴ W⁴² 4500 R³⁰ G⁴ W⁴² 4501 R³¹ G⁴ W⁴² 4502 R³² G⁴ W⁴² 4503 R³³ G⁴ W⁴² 4504 R³⁴ G⁴ W⁴² 4505 R³⁵ G⁴ W⁴² 4506 R³⁶ G⁴ W⁴² 4507 R³⁷ G⁴ W⁴² 4508 R³⁸ G⁴ W⁴² 4509 R³⁹ G⁴ W⁴² 4510 R⁴⁰ G⁴ W⁴² 4511 R⁴¹ G⁴ W⁴² 4512 R⁴² G⁴ W⁴² 4513 R⁴³ G⁴ W⁴² 4514 R⁴⁴ G⁴ W⁴² 4515 R⁴⁵ G⁴ W⁴² 4516 R⁴⁶ G⁴ W⁴² 4517 R⁴⁷ G⁴ W⁴² 4518 R⁴⁸ G⁴ W⁴² 4519 R⁴⁹ G⁴ W⁴² 4520 R⁵⁰ G⁴ W⁴² 4521 R¹ G¹ W⁴² 4522 R² G¹ W⁴² 4523 R⁴ G¹ W⁴² 4524 R⁵ G¹ W⁴² 4525 R⁷ G¹ W⁴² 4526 R⁸ G¹ W⁴² 4527 R¹⁰ G¹ W⁴² 4528 R¹² G¹ W⁴² 4529 R¹⁴ G¹ W⁴² 4530 R¹⁵ G¹ W⁴² 4531 R¹⁹ G¹ W⁴² 4532 R²⁷ G¹ W⁴² 4533 R²⁸ G¹ W⁴² 4534 R³³ G¹ W⁴² 4535 R³⁸ G¹ W⁴² 4536 R³⁹ G¹ W⁴² 4537 R⁴¹ G¹ W⁴² 4538 R⁴⁶ G¹ W⁴² 4539 R⁴⁷ G¹ W⁴² 4540 R⁴⁹ G¹ W⁴² 4541 R¹ G³ W⁴² 4542 R² G³ W⁴² 4543 R⁴ G³ W⁴² 4544 R⁵ G³ W⁴² 4545 R⁷ G³ W⁴² 4546 R⁸ G³ W⁴² 4547 R¹⁰ G³ W⁴² 4548 R¹² G³ W⁴² 4549 R¹⁴ G³ W⁴² 4550 R¹⁵ G³ W⁴² 4551 R¹⁹ G³ W⁴² 4552 R²⁷ G³ W⁴² 4553 R²⁸ G³ W⁴² 4554 R³³ G³ W⁴² 4555 R³⁸ G³ W⁴² 4556 R³⁹ G³ W⁴² 4557 R⁴¹ G³ W⁴² 4558 R⁴⁶ G³ W⁴² 4559 R⁴⁷ G³ W⁴² 4560 R⁴⁹ G³ W⁴² 4561 R¹ G⁹ W⁴² 4562 R² G⁹ W⁴² 4563 R⁴ G⁹ W⁴² 4564 R⁵ G⁹ W⁴² 4565 R⁷ G⁹ W⁴² 4566 R⁸ G⁹ W⁴² 4567 R¹⁰ G⁹ W⁴² 4568 R¹² G⁹ W⁴² 4569 R¹⁴ G⁹ W⁴² 4570 R¹⁵ G⁹ W⁴² 4571 R¹⁹ G⁹ W⁴² 4572 R²⁷ G⁹ W⁴² 4573 R²⁸ G⁹ W⁴² 4574 R³³ G⁹ W⁴² 4575 R³⁸ G⁹ W⁴² 4576 R³⁹ G⁹ W⁴² 4577 R⁴¹ G⁹ W⁴² 4578 R⁴⁶ G⁹ W⁴² 4579 R⁴⁷ G⁹ W⁴² 4580 R⁴⁹ G⁹ W⁴² 4581 R¹ G¹⁰ W⁴² 4582 R² G¹⁰ W⁴² 4583 R⁴ G¹⁰ W⁴² 4584 R⁵ G¹⁰ W⁴² 4585 R⁷ G¹⁰ W⁴² 4586 R⁸ G¹⁰ W⁴² 4587 R¹⁰ G¹⁰ W⁴² 4588 R¹² G¹⁰ W⁴² 4589 R¹⁴ G¹⁰ W⁴² 4590 R¹⁵ G¹⁰ W⁴² 4591 R¹⁹ G¹⁰ W⁴² 4592 R²⁷ G¹⁰ W⁴² 4593 R²⁸ G¹⁰ W⁴² 4594 R³³ G¹⁰ W⁴² 4595 R³⁸ G¹⁰ W⁴² 4596 R³⁹ G¹⁰ W⁴² 4597 R⁴¹ G¹⁰ W⁴² 4598 R⁴⁶ G¹⁰ W⁴² 4599 R⁴⁷ G¹⁰ W⁴² 4600 R⁴⁹ G¹⁰ W⁴² 4601 R¹ G¹² W⁴² 4602 R² G¹² W⁴² 4603 R⁴ G¹² W⁴² 4604 R⁵ G¹² W⁴² 4605 R⁷ G¹² W⁴² 4606 R⁸ G¹² W⁴² 4607 R¹⁰ G¹² W⁴² 4608 R¹² G¹² W⁴² 4609 R¹⁴ G¹² W⁴² 4610 R¹⁵ G¹² W⁴² 4611 R¹⁹ G¹² W⁴² 4612 R²⁷ G¹² W⁴² 4613 R²⁸ G¹² W⁴² 4614 R³³ G¹² W⁴² 4615 R³⁸ G¹² W⁴² 4616 R³⁹ G¹² W⁴² 4617 R⁴¹ G¹² W⁴² 4618 R⁴⁶ G¹² W⁴² 4619 R⁴⁷ G¹² W⁴² 4620 R⁴⁹ G¹² W⁴² 4621 R¹ G¹³ W⁴² 4622 R² G¹³ W⁴² 4623 R⁴ G¹³ W⁴² 4624 R⁵ G¹³ W⁴² 4625 R⁷ G¹³ W⁴² 4626 R⁸ G¹³ W⁴² 4627 R¹⁰ G¹³ W⁴² 4628 R¹² G¹³ W⁴² 4629 R¹⁴ G¹³ W⁴² 4630 R¹⁵ G¹³ W⁴² 4631 R¹⁹ G¹³ W⁴² 4632 R²⁷ G¹³ W⁴² 4633 R²⁸ G¹³ W⁴² 4634 R³³ G¹³ W⁴² 4635 R³⁸ G¹³ W⁴² 4636 R³⁹ G¹³ W⁴² 4637 R⁴¹ G¹³ W⁴² 4638 R⁴⁶ G¹³ W⁴² 4639 R⁴⁷ G¹³ W⁴² 4640 R⁴⁹ G¹³ W⁴² 4641 R¹ G¹⁶ W⁴² 4642 R² G¹⁶ W⁴² 4643 R⁴ G¹⁶ W⁴² 4644 R⁵ G¹⁶ W⁴² 4645 R⁷ G¹⁶ W⁴² 4646 R⁸ G¹⁶ W⁴² 4647 R¹⁰ G¹⁶ W⁴² 4648 R¹² G¹⁶ W⁴² 4649 R¹⁴ G¹⁶ W⁴² 4650 R¹⁵ G¹⁶ W⁴² 4651 R¹⁹ G¹⁶ W⁴² 4652 R²⁷ G¹⁶ W⁴² 4653 R²⁸ G¹⁶ W⁴² 4654 R³³ G¹⁶ W⁴² 4655 R³⁸ G¹⁶ W⁴² 4656 R³⁹ G¹⁶ W⁴² 4657 R⁴¹ G¹⁶ W⁴² 4658 R⁴⁶ G¹⁶ W⁴² 4659 R⁴⁷ G¹⁶ W⁴² 4660 R⁴⁹ G¹⁶ W⁴² 4661 R¹ G¹⁷ W⁴² 4662 R² G¹⁷ W⁴² 4663 R⁴ G¹⁷ W⁴² 4664 R⁵ G¹⁷ W⁴² 4665 R⁷ G¹⁷ W⁴² 4666 R⁸ G¹⁷ W⁴² 4667 R¹⁰ G¹⁷ W⁴² 4668 R¹² G¹⁷ W⁴² 4669 R¹⁴ G¹⁷ W⁴² 4670 R¹⁵ G¹⁷ W⁴² 4671 R¹⁹ G¹⁷ W⁴² 4672 R²⁷ G¹⁷ W⁴² 4673 R²⁸ G¹⁷ W⁴² 4674 R³³ G¹⁷ W⁴² 4675 R³⁸ G¹⁷ W⁴² 4676 R³⁹ G¹⁷ W⁴² 4677 R⁴¹ G¹⁷ W⁴² 4678 R⁴⁶ G¹⁷ W⁴² 4679 R⁴⁷ G¹⁷ W⁴² 4680 R⁴⁹ G¹⁷ W⁴² 4681 R¹ G²² W⁴² 4682 R² G²² W⁴² 4683 R⁴ G²² W⁴² 4684 R⁵ G²² W⁴² 4685 R⁷ G²² W⁴² 4686 R⁸ G²² W⁴² 4687 R¹⁰ G²² W⁴² 4688 R¹² G²² W⁴² 4689 R¹⁴ G²² W⁴² 4690 R¹⁵ G²² W⁴² 4691 R¹⁹ G²² W⁴² 4692 R²⁷ G²² W⁴² 4693 R²⁸ G²² W⁴² 4694 R³³ G²² W⁴² 4695 R³⁸ G²² W⁴² 4696 R³⁹ G²² W⁴² 4697 R⁴¹ G²² W⁴² 4698 R⁴⁶ G²² W⁴² 4699 R⁴⁷ G²² W⁴² 4700 R⁴⁹ G²² W⁴² 4701 R¹ G²³ W⁴² 4702 R² G²³ W⁴² 4703 R⁴ G²³ W⁴² 4704 R⁵ G²³ W⁴² 4705 R⁷ G²³ W⁴² 4706 R⁸ G²³ W⁴² 4707 R¹⁰ G²³ W⁴² 4708 R¹² G²³ W⁴² 4709 R¹⁴ G²³ W⁴² 4710 R¹⁵ G²³ W⁴² 4711 R¹⁹ G²³ W⁴² 4712 R²⁷ G²³ W⁴² 4713 R²⁸ G²³ W⁴² 4714 R³³ G²³ W⁴² 4715 R³⁸ G²³ W⁴² 4716 R³⁹ G²³ W⁴² 4717 R⁴¹ G²³ W⁴² 4718 R⁴⁶ G²³ W⁴² 4719 R⁴⁷ G²³ W⁴² 4720 R⁴⁹ G²³ W⁴² 4721 R¹ G²⁴ W⁴² 4722 R² G²⁴ W⁴² 4723 R⁴ G²⁴ W⁴² 4724 R⁵ G²⁴ W⁴² 4725 R⁷ G²⁴ W⁴² 4726 R⁸ G²⁴ W⁴² 4727 R¹⁰ G²⁴ W⁴² 4728 R¹² G²⁴ W⁴² 4729 R¹⁴ G²⁴ W⁴² 4730 R¹⁵ G²⁴ W⁴² 4731 R¹⁹ G²⁴ W⁴² 4732 R²⁷ G²⁴ W⁴² 4733 R²⁸ G²⁴ W⁴² 4734 R³³ G²⁴ W⁴² 4735 R³⁸ G²⁴ W⁴² 4736 R³⁹ G²⁴ W⁴² 4737 R⁴¹ G²⁴ W⁴² 4738 R⁴⁶ G²⁴ W⁴² 4739 R⁴⁷ G²⁴ W⁴² 4740 R⁴⁹ G²⁴ W⁴²

wherein R¹ to R⁵⁰ have the following structures:

wherein G¹ to G⁴⁰ have the following structures:

wherein W¹ to W⁴² have the following structures:


12. The compound of claim 1, wherein the compound has a formula of M(L_(A))_(p)(L_(B))_(q)(L_(C))_(r) wherein L_(B) and L_(C) are each a bidentate ligand; and wherein p is 1, 2, or 3; q is 0, 1, or 2; r is 0, 1, or 2; and p+q+r is the oxidation state of the metal M; or the compound has a formula selected from the group consisting of Ir(L_(A))₃, Ir(L_(A))(L_(B))₂, Ir(L_(A))₂(L_(B)), Ir(L_(A))₂(L_(C)), and Ir(L_(A))(L_(B))(L_(C)); and wherein L_(A), L_(B), and L_(C) are different from each other, or a formula of Pt(L_(A))(L_(B)); and wherein L_(A) and L_(B) can be same or different.
 13. The compound of claim 12, wherein L_(B) and L_(C) are each independently selected from the group consisting of:

wherein: T is selected from the group consisting of B, Al, Ga, and In; each of Y¹ to Y¹³ is independently selected from the group consisting of carbon and nitrogen; Y′ is selected from the group consisting of BR_(e), NR_(e), PR_(e), O, S, Se, C═O, S═O, SO₂, CR_(e)R_(f), SiR_(e)R_(f), and GeR_(e)R_(f); R_(e) and R_(f) can be fused or joined to form a ring; each R_(a), R_(b), R_(c), and R_(d) independently represents zero, mono, or up to a maximum allowed number of substitutions to its associated ring; each of R_(a1), R_(b1), R_(c1), R_(d1), R_(a), R_(b), R_(c), R_(d), R_(e) and R_(f) is independently a hydrogen or a substituent selected from the group consisting of the general substitutents defined herein; and and any two adjacent R_(a), R_(b), R_(c), R_(d), R_(e) and R_(f) can be fused or joined to form a ring or form a multidentate ligand.
 14. The compound of claim 12, wherein when the compound has formula Ir(L_(Ai-m))₃, is an integer from 1 to 1560; m is an integer from 1 to 18; and the compound is selected from the group consisting of Ir(L_(A1-1))₃ to Ir(L_(A1560-18))₃; when the compound has formula Ir(L_(Ai-m′))₃, i is an integer from 1 to 4420; m′ is an integer from 19 to 54; and the compound is selected from the group consisting of Ir(L_(A1-19))₃ to Ir(L_(A4420-54))₃; when the compound has formula Ir(L_(Ai′-m″))₃, i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; and the compound is selected from the group consisting of Ir(L_(A4421-55))₃ to Ir(L_(A4740-69))₃; when the compound has formula Ir(L_(Ai-m))(L_(Bk))₂, i is an integer from 1 to 1560; m is an integer from 1 to 18; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A1-1))(L_(B1))₂ to Ir(L_(A1560-18))(L_(B324))₂; when the compound has formula Ir(L_(Ai-m′))(L_(Bk))₂, i is an integer from 1 to 4420; m′ is an integer from 19 to 54; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A1-19))(L_(B1))₂ to Ir(L_(A4420-54))(L_(B324))₂; when the compound has formula Ir(L_(Ai′-m″))(L_(Bk))₂, i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A4421-55))(L_(B1))₂ to Ir(L_(A4740-69))(L_(B324))₂; when the compound has formula Ir(L_(Ai-m))₂(L_(Bk)), i is an integer from 1 to 1560; m is an integer from 1 to 18; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A1-1))₂(L_(B1)) to Ir(L_(A1560-18))₂(L_(B324)); when the compound has formula Ir(L_(Ai-m′))₂(L_(Bk)), i is an integer from 1 to 4420; m′ is an integer from 19 to 54; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A1-19))₂(L_(B1)) to Ir(L_(A4420-54))₂(L_(B324)); when the compound has formula Ir(L_(Ai′-m″))₂(L_(Bk)), i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; k is an integer from 1 to 324; and the compound is selected from the group consisting of Ir(L_(A4421-55))₂(L_(B1)) to Ir(L_(A4740-69))₂(L_(B324)); when the compound has formula Ir(L_(Ai-m))₂(L_(Cj-I)), i is an integer from 1 to 1560; m is an integer from 1 to 18; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A1-1))₂(L_(C1-I)) to Ir(L_(A1560-18)) (L_(C1416-I)); when the compound has formula Ir(L_(Ai-m′))₂(L_(Cj-I)), i is an integer from 1 to 4420; m′ is an integer from 19 to 54; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A1-19))₂(L_(C1-I)) to Ir(L_(A4420-54)) (L_(C1416-I)); when the compound has formula Ir(L_(Ai-m″))₂(L_(Cj-I)), i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A4421-55))₂(L_(C1-I)) to Ir(L_(A4740-69)) (L_(C1416-I)); when the compound has formula Ir(L_(Ai-m))₂(L_(Cj-II)), i is an integer from 1 to 1560; m is an integer from 1 to 18; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A1-1))₂(L_(C1-II)) to Ir(L_(A1560-18)) (L_(C1416-II)); when the compound has formula Ir(L_(Ai-m′))₂(L_(Cj-II)), i is an integer from 1 to 4420; m′ is an integer from 19 to 54; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A1-19))₂(L_(C1-II)) to Ir(L_(A4420-54)) (L_(C1416-II)); and when the compound has formula Ir(L_(Ai′-m″))₂(L_(Cj-II)), i′ is an integer from 4421 to 4740; m″ is an integer from 55 to 69; j is an integer from 1 to 1416; and the compound is selected from the group consisting of Ir(L_(A4421-55))₂(L_(C1-II)) to Ir(L_(A4740-69)) (L_(C1416-II)); wherein the structures of each L_(Ai-m), L_(Ai-m′), and L_(Ai′-m″) are defined in claim 35; wherein each L_(Bk) has the structure as follows:

wherein each L_(Cj-I) has a structure based on formula

and each L_(Cj-II) has a structure based on formula

wherein for each L_(Cj) in L_(Cj-I) and L_(Cj-II), R²⁰¹ and R²⁰² are each independently defined as follows: L_(Cj) R²⁰¹ R²⁰² L_(Cj) R²⁰¹ R²⁰² L_(Cj) R²⁰¹ R²⁰² L_(Cj) R²⁰¹ R²⁰² L_(C1) R^(D1) R^(D1) L_(C193) R^(D1) R^(D3) L_(C385) R^(D17) R^(D40) L_(C577) R^(D143) R^(D120) L_(C2) R^(D2) R^(D2) L_(C194) R^(D1) R^(D4) L_(C386) R^(D17) R^(D41) L_(C578) R^(D143) R^(D133) L_(C3) R^(D3) R^(D3) L_(C195) R^(D1) R^(D5) L_(C387) R^(D17) R^(D42) L_(C579) R^(D143) R^(D134) L_(C4) R^(D4) R^(D4) L_(C196) R^(D1) R^(D9) L_(C388) R^(D17) R^(D43) L_(C580) R^(D143) R^(D135) L_(C5) R^(D5) R^(D5) L_(C197) R^(D1) R^(D10) L_(C389) R^(D17) R^(D48) L_(C581) R^(D143) R^(D136) L_(C6) R^(D6) R^(D6) L_(C198) R^(D1) R^(D17) L_(C390) R^(D17) R^(D49) L_(C582) R^(D143) R^(D144) L_(C7) R^(D7) R^(D7) L_(C199) R^(D1) R^(D18) L_(C391) R^(D17) R^(D50) L_(C583) R^(D143) R^(D145) L_(C8) R^(D8) R^(D8) L_(C200) R^(D1) R^(D20) L_(C392) R^(D17) R^(D54) L_(C584) R^(D143) R^(D146) L_(C9) R^(D9) R^(D9) L_(C201) R^(D1) R^(D22) L_(C393) R^(D17) R^(D55) L_(C585) R^(D143) R^(D147) L_(C10) R^(D10) R^(D10) L_(C202) R^(D1) R^(D37) L_(C394) R^(D17) R^(D58) L_(C586) R^(D143) R^(D149) L_(C11) R^(D11) R^(D11) L_(C203) R^(D1) R^(D40) L_(C395) R^(D17) R^(D59) L_(C587) R^(D143) R^(D151) L_(C12) R^(D12) R^(D12) L_(C204) R^(D1) R^(D41) L_(C396) R^(D17) R^(D78) L_(C588) R^(D143) R^(D154) L_(C13) R^(D13) R^(D13) L_(C205) R^(D1) R^(D42) L_(C397) R^(D17) R^(D79) L_(C589) R^(D143) R^(D155) L_(C14) R^(D14) R^(D14) L_(C206) R^(D1) R^(D43) L_(C398) R^(D17) R^(D81) L_(C590) R^(D143) R^(D161) L_(C15) R^(D15) R^(D15) L_(C207) R^(D1) R^(D48) L_(C399) R^(D17) R^(D87) L_(C591) R^(D143) R^(D175) L_(C16) R^(D16) R^(D16) L_(C208) R^(D1) R^(D49) L_(C400) R^(D17) R^(D88) L_(C592) R^(D144) R^(D3) L_(C17) R^(D17) R^(D17) L_(C209) R^(D1) R^(D50) L_(C401) R^(D17) R^(D89) L_(C593) R^(D144) R^(D5) L_(C18) R^(D18) R^(D18) L_(C210) R^(D1) R^(D54) L_(C402) R^(D17) R^(D93) L_(C594) R^(D144) R^(D17) L_(C19) R^(D19) R^(D19) L_(C211) R^(D1) R^(D55) L_(C403) R^(D17) R^(D116) L_(C595) R^(D144) R^(D18) L_(C20) R^(D20) R^(D20) L_(C212) R^(D1) R^(D58) L_(C404) R^(D17) R^(D117) L_(C596) R^(D144) R^(D20) L_(C21) R^(D21) R^(D21) L_(C213) R^(D1) R^(D59) L_(C405) R^(D17) R^(D118) L_(C597) R^(D144) R^(D22) L_(C22) R^(D22) R^(D22) L_(C214) R^(D1) R^(D78) L_(C406) R^(D17) R^(D119) L_(C598) R^(D144) R^(D37) L_(C23) R^(D23) R^(D23) L_(C215) R^(D1) R^(D79) L_(C407) R^(D17) R^(D120) L_(C599) R^(D144) R^(D40) L_(C24) R^(D24) R^(D24) L_(C216) R^(D1) R^(D81) L_(C408) R^(D17) R^(D133) L_(C600) R^(D144) R^(D41) L_(C25) R^(D25) R^(D25) L_(C217) R^(D1) R^(D87) L_(C409) R^(D17) R^(D134) L_(C601) R^(D144) R^(D42) L_(C26) R^(D26) R^(D26) L_(C218) R^(D1) R^(D88) L_(C410) R^(D17) R^(D135) L_(C602) R^(D144) R^(D43) L_(C27) R^(D27) R^(D27) L_(C219) R^(D1) R^(D89) L_(C411) R^(D17) R^(D136) L_(C603) R^(D144) R^(D48) L_(C28) R^(D28) R^(D28) L_(C220) R^(D1) R^(D93) L_(C412) R^(D17) R^(D143) L_(C604) R^(D144) R^(D49) L_(C29) R^(D29) R^(D29) L_(C221) R^(D1) R^(D116) L_(C413) R^(D17) R^(D144) L_(C605) R^(D144) R^(D54) L_(C30) R^(D30) R^(D30) L_(C222) R^(D1) R^(D117) L_(C414) R^(D17) R^(D145) L_(C606) R^(D144) R^(D58) L_(C31) R^(D31) R^(D31) L_(C223) R^(D1) R^(D118) L_(C415) R^(D17) R^(D146) L_(C607) R^(D144) R^(D59) L_(C32) R^(D32) R^(D32) L_(C224) R^(D1) R^(D119) L_(C416) R^(D17) R^(D147) L_(C608) R^(D144) R^(D78) L_(C33) R^(D33) R^(D33) L_(C225) R^(D1) R^(D120) L_(C417) R^(D17) R^(D149) L_(C609) R^(D144) R^(D79) L_(C34) R^(D34) R^(D34) L_(C226) R^(D1) R^(D133) L_(C418) R^(D17) R^(D151) L_(C610) R^(D144) R^(D81) L_(C35) R^(D35) R^(D35) L_(C227) R^(D1) R^(D134) L_(C419) R^(D17) R^(D154) L_(C611) R^(D144) R^(D87) L_(C36) R^(D36) R^(D36) L_(C228) R^(D1) R^(D135) L_(C420) R^(D17) R^(D155) L_(C612) R^(D144) R^(D88) L_(C37) R^(D37) R^(D37) L_(C229) R^(D1) R^(D136) L_(C421) R^(D17) R^(D161) L_(C613) R^(D144) R^(D89) L_(C38) R^(D38) R^(D38) L_(C230) R^(D1) R^(D143) L_(C422) R^(D17) R^(D175) L_(C614) R^(D144) R^(D93) L_(C39) R^(D39) R^(D39) L_(C231) R^(D1) R^(D144) L_(C423) R^(D50) R^(D3) L_(C615) R^(D144) R^(D116) L_(C10) R^(D40) R^(D40) L_(C232) R^(D1) R^(D145) L_(C424) R^(D50) R^(D5) L_(C616) R^(D144) R^(D117) L_(C41) R^(D41) R^(D41) L_(C233) R^(D1) R^(D146) L_(C425) R^(D50) R^(D18) L_(C617) R^(D144) R^(D118) L_(C42) R^(D42) R^(D42) L_(C234) R^(D1) R^(D147) L_(C426) R^(D50) R^(D20) L_(C618) R^(D144) R^(D119) L_(C43) R^(D43) R^(D43) L_(C235) R^(D1) R^(D149) L_(C427) R^(D50) R^(D22) L_(C619) R^(D144) R^(D120) L_(C44) R^(D44) R^(D44) L_(C236) R^(D1) R^(D151) L_(C428) R^(D50) R^(D37) L_(C620) R^(D144) R^(D133) L_(C45) R^(D45) R^(D45) L_(C237) R^(D1) R^(D154) L_(C429) R^(D50) R^(D40) L_(C621) R^(D144) R^(D134) L_(C46) R^(D46) R^(D46) L_(C238) R^(D1) R^(D155) L_(C430) R^(D50) R^(D41) L_(C622) R^(D144) R^(D135) L_(C47) R^(D47) R^(D47) L_(C239) R^(D1) R^(D161) L_(C431) R^(D50) R^(D42) L_(C623) R^(D144) R^(D136) L_(C48) R^(D48) R^(D48) L_(C240) R^(D1) R^(D175) L_(C432) R^(D50) R^(D43) L_(C624) R^(D144) R^(D145) L_(C49) R^(D49) R^(D49) L_(C241) R^(D4) R^(D3) L_(C433) R^(D50) R^(D48) L_(C625) R^(D144) R^(D146) L_(C50) R^(D50) R^(D50) L_(C242) R^(D4) R^(D5) L_(C434) R^(D50) R^(D49) L_(C626) R^(D144) R^(D147) L_(C51) R^(D51) R^(D51) L_(C243) R^(D4) R^(D9) L_(C435) R^(D50) R^(D54) L_(C627) R^(D144) R^(D149) L_(C52) R^(D52) R^(D52) L_(C244) R^(D4) R^(D10) L_(C436) R^(D50) R^(D55) L_(C628) R^(D144) R^(D151) L_(C53) R^(D55) R^(D55) L_(C245) R^(D4) R^(D17) L_(C437) R^(D50) R^(D58) L_(C629) R^(D144) R^(D154) L_(C54) R^(D54) R^(D54) L_(C246) R^(D4) R^(D18) L_(C438) R^(D50) R^(D59) L_(C630) R^(D144) R^(D155) L_(C55) R^(D55) R^(D55) L_(C247) R^(D4) R^(D20) L_(C439) R^(D50) R^(D78) L_(C631) R^(D144) R^(D161) L_(C56) R^(D56) R^(D56) L_(C248) R^(D4) R^(D22) L_(C440) R^(D50) R^(D79) L_(C632) R^(D144) R^(D175) L_(C57) R^(D57) R^(D57) L_(C249) R^(D4) R^(D37) L_(C441) R^(D50) R^(D81) L_(C633) R^(D145) R^(D3) L_(C58) R^(D58) R^(D58) L_(C250) R^(D4) R^(D40) L_(C442) R^(D50) R^(D87) L_(C634) R^(D145) R^(D5) L_(C59) R^(D59) R^(D59) L_(C251) R^(D4) R^(D41) L_(C443) R^(D50) R^(D88) L_(C635) R^(D145) R^(D17) L_(C60) R^(D60) R^(D60) L_(C252) R^(D4) R^(D42) L_(C444) R^(D50) R^(D89) L_(C636) R^(D145) R^(D18) L_(C61) R^(D61) R^(D61) L_(C253) R^(D4) R^(D43) L_(C445) R^(D50) R^(D93) L_(C637) R^(D145) R^(D20) L_(C62) R^(D62) R^(D62) L_(C254) R^(D4) R^(D48) L_(C446) R^(D50) R^(D116) L_(C638) R^(D145) R^(D22) L_(C63) R^(D63) R^(D63) L_(C255) R^(D4) R^(D49) L_(C447) R^(D50) R^(D117) L_(C639) R^(D145) R^(D37) L_(C64) R^(D64) R^(D64) L_(C256) R^(D4) R^(D50) L_(C448) R^(D50) R^(D118) L_(C640) R^(D145) R^(D40) L_(C65) R^(D65) R^(D65) L_(C257) R^(D4) R^(D54) L_(C449) R^(D50) R^(D119) L_(C641) R^(D145) R^(D41) L_(C66) R^(D66) R^(D66) L_(C258) R^(D4) R^(D55) L_(C450) R^(D50) R^(D120) L_(C642) R^(D145) R^(D42) L_(C67) R^(D67) R^(D67) L_(C259) R^(D4) R^(D58) L_(C451) R^(D50) R^(D133) L_(C643) R^(D145) R^(D43) L_(C68) R^(D68) R^(D68) L_(C260) R^(D4) R^(D59) L_(C452) R^(D50) R^(D134) L_(C644) R^(D145) R^(D48) L_(C69) R^(D69) R^(D69) L_(C261) R^(D4) R^(D78) L_(C453) R^(D50) R^(D135) L_(C645) R^(D145) R^(D49) L_(C70) R^(D70) R^(D70) L_(C262) R^(D4) R^(D79) L_(C454) R^(D50) R^(D136) L_(C646) R^(D145) R^(D54) L_(C71) R^(D71) R^(D71) L_(C263) R^(D4) R^(D81) L_(C455) R^(D50) R^(D143) L_(C647) R^(D145) R^(D58) L_(C72) R^(D72) R^(D72) L_(C264) R^(D4) R^(D87) L_(C456) R^(D50) R^(D144) L_(C648) R^(D145) R^(D59) L_(C73) R^(D73) R^(D73) L_(C265) R^(D4) R^(D88) L_(C457) R^(D50) R^(D145) L_(C649) R^(D145) R^(D78) L_(C74) R^(D74) R^(D74) L_(C266) R^(D4) R^(D89) L_(C458) R^(D50) R^(D146) L_(C650) R^(D145) R^(D79) L_(C75) R^(D75) R^(D75) L_(C267) R^(D4) R^(D93) L_(C459) R^(D50) R^(D147) L_(C651) R^(D145) R^(D81) L_(C76) R^(D76) R^(D76) L_(C268) R^(D4) R^(D116) L_(C460) R^(D50) R^(D149) L_(C652) R^(D145) R^(D87) L_(C77) R^(D77) R^(D77) L_(C269) R^(D4) R^(D117) L_(C461) R^(D50) R^(D151) L_(C653) R^(D145) R^(D88) L_(C78) R^(D78) R^(D78) L_(C270) R^(D4) R^(D118) L_(C462) R^(D50) R^(D154) L_(C654) R^(D145) R^(D89) L_(C79) R^(D79) R^(D79) L_(C271) R^(D4) R^(D119) L_(C463) R^(D50) R^(D155) L_(C655) R^(D145) R^(D93) L_(C80) R^(D80) R^(D80) L_(C272) R^(D4) R^(D120) L_(C464) R^(D50) R^(D161) L_(C656) R^(D145) R^(D116) L_(C81) R^(D81) R^(D81) L_(C273) R^(D4) R^(D133) L_(C465) R^(D50) R^(D175) L_(C657) R^(D145) R^(D117) L_(C82) R^(D82) R^(D82) L_(C274) R^(D4) R^(D134) L_(C466) R^(D55) R^(D3) L_(C658) R^(D145) R^(D118) L_(C83) R^(D83) R^(D83) L_(C275) R^(D4) R^(D135) L_(C467) R^(D55) R^(D5) L_(C659) R^(D145) R^(D119) L_(C84) R^(D84) R^(D84) L_(C276) R^(D4) R^(D136) L_(C468) R^(D55) R^(D18) L_(C660) R^(D145) R^(D120) L_(C85) R^(D85) R^(D85) L_(C277) R^(D4) R^(D143) L_(C469) R^(D55) R^(D20) L_(C661) R^(D145) R^(D133) L_(C86) R^(D86) R^(D86) L_(C278) R^(D4) R^(D144) L_(C470) R^(D55) R^(D22) L_(C662) R^(D145) R^(D134) L_(C87) R^(D87) R^(D87) L_(C279) R^(D4) R^(D145) L_(C471) R^(D55) R^(D37) L_(C663) R^(D145) R^(D135) L_(C88) R^(D88) R^(D88) L_(C280) R^(D4) R^(D146) L_(C472) R^(D55) R^(D40) L_(C664) R^(D145) R^(D136) L_(C89) R^(D89) R^(D89) L_(C281) R^(D4) R^(D147) L_(C473) R^(D55) R^(D41) L_(C665) R^(D145) R^(D146) L_(C90) R^(D90) R^(D90) L_(C282) R^(D4) R^(D149) L_(C474) R^(D55) R^(D42) L_(C666) R^(D145) R^(D147) L_(C91) R^(D91) R^(D91) L_(C283) R^(D4) R^(D151) L_(C475) R^(D55) R^(D43) L_(C667) R^(D145) R^(D149) L_(C92) R^(D92) R^(D92) L_(C284) R^(D4) R^(D154) L_(C476) R^(D55) R^(D48) L_(C668) R^(D145) R^(D151) L_(C93) R^(D93) R^(D93) L_(C285) R^(D4) R^(D155) L_(C477) R^(D55) R^(D49) L_(C669) R^(D145) R^(D154) L_(C94) R^(D94) R^(D94) L_(C286) R^(D4) R^(D161) L_(C478) R^(D55) R^(D54) L_(C670) R^(D145) R^(D155) L_(C95) R^(D95) R^(D95) L_(C287) R^(D4) R^(D175) L_(C479) R^(D55) R^(D58) L_(C671) R^(D145) R^(D161) L_(C96) R^(D96) R^(D96) L_(C288) R^(D9) R^(D3) L_(C480) R^(D55) R^(D59) L_(C672) R^(D145) R^(D175) L_(C97) R^(D97) R^(D97) L_(C289) R^(D9) R^(D5) L_(C481) R^(D55) R^(D78) L_(C673) R^(D146) R^(D3) L_(C98) R^(D98) R^(D98) L_(C290) R^(D9) R^(D10) L_(C482) R^(D55) R^(D79) L_(C674) R^(D146) R^(D5) L_(C99) R^(D99) R^(D99) L_(C291) R^(D9) R^(D17) L_(C483) R^(D55) R^(D81) L_(C675) R^(D146) R^(D17) L_(C100) R^(D100) R^(D100) L_(C292) R^(D9) R^(D18) L_(C484) R^(D55) R^(D87) L_(C676) R^(D146) R^(D18) L_(C101) R^(D101) R^(D101) L_(C293) R^(D9) R^(D20) L_(C485) R^(D55) R^(D88) L_(C677) R^(D146) R^(D20) L_(C102) R^(D102) R^(D102) L_(C294) R^(D9) R^(D22) L_(C486) R^(D55) R^(D89) L_(C678) R^(D146) R^(D22) L_(C103) R^(D103) R^(D103) L_(C295) R^(D9) R^(D37) L_(C487) R^(D55) R^(D93) L_(C679) R^(D146) R^(D37) L_(C104) R^(D104) R^(D104) L_(C296) R^(D9) R^(D40) L_(C488) R^(D55) R^(D116) L_(C680) R^(D146) R^(D40) L_(C105) R^(D105) R^(D105) L_(C297) R^(D9) R^(D41) L_(C489) R^(D55) R^(D117) L_(C681) R^(D146) R^(D41) L_(C106) R^(D106) R^(D106) L_(C298) R^(D9) R^(D42) L_(C490) R^(D55) R^(D118) L_(C682) R^(D146) R^(D42) L_(C107) R^(D107) R^(D107) L_(C299) R^(D9) R^(D43) L_(C491) R^(D55) R^(D119) L_(C683) R^(D146) R^(D43) L_(C108) R^(D108) R^(D108) L_(C300) R^(D9) R^(D48) L_(C492) R^(D55) R^(D120) L_(C684) R^(D146) R^(D48) L_(C109) R^(D109) R^(D109) L_(C301) R^(D9) R^(D49) L_(C493) R^(D55) R^(D133) L_(C685) R^(D146) R^(D49) L_(C110) R^(D110) R^(D110) L_(C302) R^(D9) R^(D50) L_(C494) R^(D55) R^(D134) L_(C686) R^(D146) R^(D54) L_(C111) R^(D111) R^(D111) L_(C303) R^(D9) R^(D54) L_(C495) R^(D55) R^(D135) L_(C687) R^(D146) R^(D58) L_(C112) R^(D112) R^(D112) L_(C304) R^(D9) R^(D55) L_(C496) R^(D55) R^(D136) L_(C688) R^(D146) R^(D59) L_(C113) R^(D113) R^(D113) L_(C305) R^(D9) R^(D58) L_(C497) R^(D55) R^(D143) L_(C689) R^(D146) R^(D78) L_(C114) R^(D114) R^(D114) L_(C306) R^(D9) R^(D59) L_(C498) R^(D55) R^(D144) L_(C690) R^(D146) R^(D79) L_(C115) R^(D115) R^(D115) L_(C307) R^(D9) R^(D78) L_(C499) R^(D55) R^(D145) L_(C691) R^(D146) R^(D81) L_(C116) R^(D116) R^(D116) L_(C308) R^(D9) R^(D79) L_(C500) R^(D55) R^(D146) L_(C692) R^(D146) R^(D87) L_(C117) R^(D117) R^(D117) L_(C309) R^(D9) R^(D81) L_(C501) R^(D55) R^(D147) L_(C693) R^(D146) R^(D88) L_(C118) R^(D118) R^(D118) L_(C310) R^(D9) R^(D87) L_(C502) R^(D55) R^(D149) L_(C694) R^(D146) R^(D89) L_(C119) R^(D119) R^(D119) L_(C311) R^(D9) R^(D88) L_(C503) R^(D55) R^(D151) L_(C695) R^(D146) R^(D93) L_(C120) R^(D120) R^(D120) L_(C312) R^(D9) R^(D89) L_(C504) R^(D55) R^(D154) L_(C696) R^(D146) R^(D117) L_(C121) R^(D121) R^(D121) L_(C313) R^(D9) R^(D93) L_(C505) R^(D55) R^(D155) L_(C697) R^(D146) R^(D118) L_(C122) R^(D122) R^(D122) L_(C314) R^(D9) R^(D116) L_(C506) R^(D55) R^(D161) L_(C698) R^(D146) R^(D119) L_(C123) R^(D123) R^(D123) L_(C315) R^(D9) R^(D117) L_(C507) R^(D55) R^(D175) L_(C699) R^(D146) R^(D120) L_(C124) R^(D124) R^(D124) L_(C316) R^(D9) R^(D118) L_(C508) R^(D116) R^(D3) L_(C700) R^(D146) R^(D133) L_(C125) R^(D125) R^(D125) L_(C317) R^(D9) R^(D119) L_(C509) R^(D116) R^(D5) L_(C701) R^(D146) R^(D134) L_(C126) R^(D126) R^(D126) L_(C318) R^(D9) R^(D120) L_(C510) R^(D116) R^(D17) L_(C702) R^(D146) R^(D135) L_(C127) R^(D127) R^(D127) L_(C319) R^(D9) R^(D133) L_(C511) R^(D116) R^(D18) L_(C703) R^(D146) R^(D136) L_(C128) R^(D128) R^(D128) L_(C320) R^(D9) R^(D134) L_(C512) R^(D116) R^(D20) L_(C704) R^(D146) R^(D146) L_(C129) R^(D129) R^(D129) L_(C321) R^(D9) R^(D135) L_(C513) R^(D116) R^(D22) L_(C705) R^(D146) R^(D147) L_(C130) R^(D130) R^(D130) L_(C322) R^(D9) R^(D136) L_(C514) R^(D116) R^(D37) L_(C706) R^(D146) R^(D149) L_(C131) R^(D131) R^(D131) L_(C323) R^(D9) R^(D143) L_(C515) R^(D116) R^(D40) L_(C707) R^(D146) R^(D151) L_(C132) R^(D132) R^(D132) L_(C324) R^(D9) R^(D144) L_(C516) R^(D116) R^(D41) L_(C708) R^(D146) R^(D154) L_(C133) R^(D133) R^(D133) L_(C325) R^(D9) R^(D145) L_(C517) R^(D116) R^(D42) L_(C709) R^(D146) R^(D155) L_(C134) R^(D134) R^(D134) L_(C326) R^(D9) R^(D146) L_(C518) R^(D116) R^(D43) L_(C710) R^(D146) R^(D161) L_(C135) R^(D135) R^(D135) L_(C327) R^(D9) R^(D147) L_(C519) R^(D116) R^(D48) L_(C711) R^(D146) R^(D175) L_(C136) R^(D136) R^(D136) L_(C328) R^(D9) R^(D149) L_(C520) R^(D116) R^(D49) L_(C712) R^(D133) R^(D3) L_(C137) R^(D137) R^(D137) L_(C329) R^(D9) R^(D151) L_(C521) R^(D116) R^(D54) L_(C713) R^(D133) R^(D5) L_(C138) R^(D138) R^(D138) L_(C330) R^(D9) R^(D154) L_(C522) R^(D116) R^(D58) L_(C714) R^(D133) R^(D3) L_(C139) R^(D139) R^(D139) L_(C331) R^(D9) R^(D155) L_(C523) R^(D116) R^(D59) L_(C715) R^(D133) R^(D18) L_(C140) R^(D140) R^(D140) L_(C332) R^(D9) R^(D161) L_(C524) R^(D116) R^(D78) L_(C716) R^(D133) R^(D20) L_(C141) R^(D141) R^(D141) L_(C333) R^(D9) R^(D175) L_(C525) R^(D116) R^(D79) L_(C717) R^(D133) R^(D22) L_(C142) R^(D142) R^(D142) L_(C334) R^(D10) R^(D3) L_(C526) R^(D116) R^(D81) L_(C718) R^(D133) R^(D37) L_(C143) R^(D143) R^(D143) L_(C335) R^(D10) R^(D5) L_(C527) R^(D116) R^(D87) L_(C719) R^(D133) R^(D40) L_(C144) R^(D144) R^(D144) L_(C336) R^(D10) R^(D17) L_(C528) R^(D116) R^(D88) L_(C720) R^(D133) R^(D41) L_(C145) R^(D145) R^(D145) L_(C337) R^(D10) R^(D18) L_(C529) R^(D116) R^(D89) L_(C721) R^(D133) R^(D42) L_(C146) R^(D146) R^(D146) L_(C338) R^(D10) R^(D20) L_(C530) R^(D116) R^(D95) L_(C722) R^(D133) R^(D43) L_(C147) R^(D147) R^(D147) L_(C339) R^(D10) R^(D22) L_(C531) R^(D116) R^(D117) L_(C723) R^(D133) R^(D48) L_(C148) R^(D148) R^(D148) L_(C340) R^(D10) R^(D37) L_(C532) R^(D116) R^(D118) L_(C724) R^(D133) R^(D49) L_(C149) R^(D149) R^(D149) L_(C341) R^(D10) R^(D40) L_(C533) R^(D116) R^(D119) L_(C725) R^(D133) R^(D54) L_(C150) R^(D150) R^(D150) L_(C342) R^(D10) R^(D41) L_(C534) R^(D116) R^(D120) L_(C726) R^(D133) R^(D58) L_(C151) R^(D151) R^(D151) L_(C343) R^(D10) R^(D42) L_(C535) R^(D116) R^(D133) L_(C727) R^(D133) R^(D59) L_(C152) R^(D152) R^(D152) L_(C344) R^(D10) R^(D43) L_(C536) R^(D116) R^(D134) L_(C728) R^(D133) R^(D78) L_(C153) R^(D153) R^(D153) L_(C345) R^(D10) R^(D48) L_(C537) R^(D116) R^(D135) L_(C729) R^(D133) R^(D79) L_(C154) R^(D154) R^(D154) L_(C346) R^(D10) R^(D49) L_(C538) R^(D116) R^(D136) L_(C730) R^(D133) R^(D81) L_(C155) R^(D155) R^(D155) L_(C347) R^(D10) R^(D50) L_(C539) R^(D116) R^(D143) L_(C731) R^(D133) R^(D87) L_(C156) R^(D156) R^(D156) L_(C348) R^(D10) R^(D54) L_(C540) R^(D116) R^(D144) L_(C732) R^(D133) R^(D88) L_(C157) R^(D157) R^(D157) L_(C349) R^(D10) R^(D55) L_(C541) R^(D116) R^(D145) L_(C733) R^(D133) R^(D89) L_(C158) R^(D158) R^(D158) L_(C350) R^(D10) R^(D58) L_(C542) R^(D116) R^(D146) L_(C734) R^(D133) R^(D93) L_(C159) R^(D159) R^(D159) L_(C351) R^(D10) R^(D59) L_(C543) R^(D116) R^(D147) L_(C735) R^(D133) R^(D117) L_(C160) R^(D160) R^(D160) L_(C352) R^(D10) R^(D78) L_(C544) R^(D116) R^(D149) L_(C736) R^(D133) R^(D118) L_(C161) R^(D161) R^(D161) L_(C353) R^(D10) R^(D79) L_(C545) R^(D116) R^(D151) L_(C737) R^(D133) R^(D119) L_(C162) R^(D162) R^(D162) L_(C354) R^(D10) R^(D81) L_(C546) R^(D116) R^(D154) L_(C738) R^(D133) R^(D120) L_(C163) R^(D163) R^(D163) L_(C355) R^(D10) R^(D87) L_(C547) R^(D116) R^(D155) L_(C739) R^(D133) R^(D133) L_(C164) R^(D164) R^(D164) L_(C356) R^(D10) R^(D88) L_(C548) R^(D116) R^(D161) L_(C740) R^(D133) R^(D134) L_(C165) R^(D165) R^(D165) L_(C357) R^(D10) R^(D89) L_(C549) R^(D116) R^(D175) L_(C741) R^(D133) R^(D135) L_(C166) R^(D166) R^(D166) L_(C358) R^(D10) R^(D93) L_(C550) R^(D143) R^(D3) L_(C742) R^(D133) R^(D136) L_(C167) R^(D167) R^(D167) L_(C359) R^(D10) R^(D116) L_(C551) R^(D143) R^(D5) L_(C743) R^(D133) R^(D146) L_(C168) R^(D168) R^(D168) L_(C360) R^(D10) R^(D117) L_(C552) R^(D143) R^(D17) L_(C744) R^(D133) R^(D147) L_(C169) R^(D169) R^(D169) L_(C361) R^(D10) R^(D118) L_(C553) R^(D143) R^(D18) L_(C745) R^(D133) R^(D149) L_(C170) R^(D170) R^(D170) L_(C362) R^(D10) R^(D119) L_(C554) R^(D143) R^(D20) L_(C746) R^(D133) R^(D151) L_(C171) R^(D171) R^(D171) L_(C363) R^(D10) R^(D120) L_(C555) R^(D143) R^(D22) L_(C747) R^(D133) R^(D154) L_(C172) R^(D172) R^(D172) L_(C364) R^(D10) R^(D133) L_(C556) R^(D143) R^(D37) L_(C748) R^(D133) R^(D155) L_(C173) R^(D173) R^(D173) L_(C365) R^(D10) R^(D134) L_(C557) R^(D143) R^(D40) L_(C749) R^(D133) R^(D161) L_(C174) R^(D174) R^(D174) L_(C366) R^(D10) R^(D135) L_(C558) R^(D143) R^(D41) L_(C750) R^(D133) R^(D175) L_(C175) R^(D175) R^(D175) L_(C367) R^(D10) R^(D136) L_(C559) R^(D143) R^(D42) L_(C751) R^(D175) R^(D3) L_(C176) R^(D176) R^(D176) L_(C368) R^(D10) R^(D143) L_(C560) R^(D143) R^(D43) L_(C752) R^(D175) R^(D5) L_(C177) R^(D177) R^(D177) L_(C369) R^(D10) R^(D144) L_(C561) R^(D143) R^(D48) L_(C753) R^(D175) R^(D18) L_(C178) R^(D178) R^(D178) L_(C370) R^(D10) R^(D145) L_(C562) R^(D143) R^(D49) L_(C754) R^(D175) R^(D20) L_(C179) R^(D179) R^(D179) L_(C371) R^(D10) R^(D146) L_(C563) R^(D143) R^(D54) L_(C755) R^(D175) R^(D22) L_(C180) R^(D180) R^(D180) L_(C372) R^(D10) R^(D147) L_(C564) R^(D143) R^(D58) L_(C756) R^(D175) R^(D37) L_(C181) R^(D181) R^(D181) L_(C373) R^(D10) R^(D149) L_(C565) R^(D143) R^(D59) L_(C757) R^(D175) R^(D40) L_(C182) R^(D182) R^(D182) L_(C374) R^(D10) R^(D151) L_(C566) R^(D143) R^(D78) L_(C758) R^(D175) R^(D41) L_(C183) R^(D183) R^(D183) L_(C375) R^(D10) R^(D154) L_(C567) R^(D143) R^(D79) L_(C759) R^(D175) R^(D42) L_(C184) R^(D184) R^(D184) L_(C376) R^(D10) R^(D155) L_(C568) R^(D143) R^(D81) L_(C760) R^(D175) R^(D43) L_(C185) R^(D185) R^(D185) L_(C377) R^(D10) R^(D161) L_(C569) R^(D143) R^(D87) L_(C761) R^(D175) R^(D48) L_(C186) R^(D186) R^(D186) L_(C378) R^(D10) R^(D175) L_(C570) R^(D143) R^(D88) L_(C762) R^(D175) R^(D49) L_(C187) R^(D187) R^(D187) L_(C379) R^(D17) R^(D3) L_(C571) R^(D143) R^(D89) L_(C763) R^(D175) R^(D54) L_(C188) R^(D188) R^(D188) L_(C380) R^(D17) R^(D5) L_(C572) R^(D143) R^(D93) L_(C764) R^(D175) R^(D58) L_(C189) R^(D189) R^(D189) L_(C381) R^(D17) R^(D18) L_(C573) R^(D143) R^(D116) L_(C765) R^(D175) R^(D59) L_(C190) R^(D190) R^(D190) L_(C382) R^(D17) R^(D20) L_(C574) R^(D143) R^(D117) L_(C766) R^(D175) R^(D78) L_(C191) R^(D191) R^(D191) L_(C383) R^(D17) R^(D22) L_(C575) R^(D143) R^(D118) L_(C767) R^(D175) R^(D79) L_(C192) R^(D192) R^(D192) L_(C384) R^(D17) R^(D37) L_(C576) R^(D143) R^(D119) L_(C768) R^(D175) R^(D81) L_(C769) R^(D193) R^(D193) L_(C877) R^(D1) R^(D193) L_(C985) R^(D4) R^(D193) L_(C1093) R^(D9) R^(D193) L_(C770) R^(D194) R^(D194) L_(C878) R^(D1) R^(D194) L_(C986) R^(D4) R^(D194) L_(C1094) R^(D9) R^(D194) L_(C771) R^(D195) R^(D195) L_(C879) R^(D1) R^(D195) L_(C987) R^(D4) R^(D195) L_(C1095) R^(D9) R^(D195) L_(C772) R^(D196) R^(D196) L_(C880) R^(D1) R^(D196) L_(C988) R^(D4) R^(D196) L_(C1096) R^(D9) R^(D196) L_(C773) R^(D197) R^(D197) L_(C881) R^(D1) R^(D197) L_(C989) R^(D4) R^(D197) L_(C1097) R^(D9) R^(D197) L_(C774) R^(D198) R^(D198) L_(C882) R^(D1) R^(D198) L_(C990) R^(D4) R^(D198) L_(C1098) R^(D9) R^(D198) L_(C775) R^(D199) R^(D199) L_(C883) R^(D1) R^(D199) L_(C991) R^(D4) R^(D199) L_(C1099) R^(D9) R^(D199) L_(C776) R^(D200) R^(D200) L_(C884) R^(D1) R^(D200) L_(C992) R^(D4) R^(D200) L_(C1100) R^(D9) R^(D200) L_(C777) R^(D201) R^(D201) L_(C885) R^(D1) R^(D201) L_(C993) R^(D4) R^(D201) L_(C1101) R^(D9) R^(D201) L_(C778) R^(D202) R^(D202) L_(C886) R^(D1) R^(D202) L_(C994) R^(D4) R^(D202) L_(C1102) R^(D9) R^(D202) L_(C779) R^(D203) R^(D203) L_(C887) R^(D1) R^(D203) L_(C995) R^(D4) R^(D203) L_(C1103) R^(D9) R^(D203) L_(C780) R^(D204) R^(D204) L_(C888) R^(D1) R^(D204) L_(C996) R^(D4) R^(D204) L_(C1104) R^(D9) R^(D204) L_(C781) R^(D205) R^(D205) L_(C889) R^(D1) R^(D205) L_(C997) R^(D4) R^(D205) L_(C1105) R^(D9) R^(D205) L_(C782) R^(D206) R^(D206) L_(C890) R^(D1) R^(D206) L_(C998) R^(D4) R^(D206) L_(C1106) R^(D9) R^(D206) L_(C783) R^(D207) R^(D207) L_(C891) R^(D1) R^(D207) L_(C999) R^(D4) R^(D207) L_(C1107) R^(D9) R^(D207) L_(C784) R^(D208) R^(D208) L_(C892) R^(D1) R^(D208) L_(C1000) R^(D4) R^(D208) L_(C1108) R^(D9) R^(D208) L_(C785) R^(D209) R^(D209) L_(C893) R^(D1) R^(D209) L_(C1001) R^(D4) R^(D209) L_(C1109) R^(D9) R^(D209) L_(C786) R^(D210) R^(D210) L_(C894) R^(D1) R^(D210) L_(C1002) R^(D4) R^(D210) L_(C1110) R^(D9) R^(D210) L_(C787) R^(D211) R^(D211) L_(C895) R^(D1) R^(D211) L_(C1003) R^(D4) R^(D211) L_(C1111) R^(D9) R^(D211) L_(C788) R^(D212) R^(D212) L_(C896) R^(D1) R^(D212) L_(C1004) R^(D4) R^(D212) L_(C1112) R^(D9) R^(D212) L_(C789) R^(D213) R^(D213) L_(C897) R^(D1) R^(D213) L_(C1005) R^(D4) R^(D213) L_(C1113) R^(D9) R^(D213) L_(C790) R^(D214) R^(D214) L_(C898) R^(D1) R^(D214) L_(C1006) R^(D4) R^(D214) L_(C1114) R^(D9) R^(D214) L_(C791) R^(D215) R^(D215) L_(C899) R^(D1) R^(D215) L_(C1007) R^(D4) R^(D215) L_(C1115) R^(D9) R^(D215) L_(C792) R^(D216) R^(D216) L_(C900) R^(D1) R^(D216) L_(C1008) R^(D4) R^(D216) L_(C1116) R^(D9) R^(D216) L_(C793) R^(D217) R^(D217) L_(C901) R^(D1) R^(D217) L_(C1009) R^(D4) R^(D217) L_(C1117) R^(D9) R^(D217) L_(C794) R^(D218) R^(D218) L_(C902) R^(D1) R^(D218) L_(C1010) R^(D4) R^(D218) L_(C1118) R^(D9) R^(D218) L_(C795) R^(D219) R^(D219) L_(C903) R^(D1) R^(D219) L_(C1011) R^(D4) R^(D219) L_(C1119) R^(D9) R^(D219) L_(C796) R^(D220) R^(D220) L_(C904) R^(D1) R^(D220) L_(C1012) R^(D4) R^(D220) L_(C1120) R^(D9) R^(D220) L_(C797) R^(D221) R^(D221) L_(C905) R^(D1) R^(D221) L_(C1013) R^(D4) R^(D221) L_(C1121) R^(D9) R^(D221) L_(C798) R^(D222) R^(D222) L_(C906) R^(D1) R^(D222) L_(C1014) R^(D4) R^(D222) L_(C1122) R^(D9) R^(D222) L_(C799) R^(D223) R^(D223) L_(C907) R^(D1) R^(D223) L_(C1015) R^(D4) R^(D223) L_(C1123) R^(D9) R^(D223) L_(C800) R^(D224) R^(D224) L_(C908) R^(D1) R^(D224) L_(C1016) R^(D4) R^(D224) L_(C1124) R^(D9) R^(D224) L_(C801) R^(D225) R^(D225) L_(C909) R^(D1) R^(D225) L_(C1017) R^(D4) R^(D225) L_(C1125) R^(D9) R^(D225) L_(C802) R^(D226) R^(D226) L_(C910) R^(D1) R^(D226) L_(C1018) R^(D4) R^(D226) L_(C1126) R^(D9) R^(D226) L_(C803) R^(D227) R^(D227) L_(C911) R^(D1) R^(D227) L_(C1019) R^(D4) R^(D227) L_(C1127) R^(D9) R^(D227) L_(C804) R^(D228) R^(D228) L_(C912) R^(D1) R^(D228) L_(C1020) R^(D4) R^(D228) L_(C1128) R^(D9) R^(D228) L_(C805) R^(D229) R^(D229) L_(C913) R^(D1) R^(D229) L_(C1021) R^(D4) R^(D229) L_(C1129) R^(D9) R^(D229) L_(C806) R^(D230) R^(D230) L_(C914) R^(D1) R^(D230) L_(C1022) R^(D4) R^(D230) L_(C1130) R^(D9) R^(D230) L_(C807) R^(D231) R^(D231) L_(C915) R^(D1) R^(D231) L_(C1023) R^(D4) R^(D231) L_(C1131) R^(D9) R^(D231) L_(C808) R^(D232) R^(D232) L_(C916) R^(D1) R^(D232) L_(C1024) R^(D4) R^(D232) L_(C1132) R^(D9) R^(D232) L_(C809) R^(D233) R^(D233) L_(C917) R^(D1) R^(D233) L_(C1025) R^(D4) R^(D233) L_(C1133) R^(D9) R^(D233) L_(C810) R^(D234) R^(D234) L_(C918) R^(D1) R^(D234) L_(C1026) R^(D4) R^(D234) L_(C1134) R^(D9) R^(D234) L_(C811) R^(D235) R^(D235) L_(C919) R^(D1) R^(D235) L_(C1027) R^(D4) R^(D235) L_(C1135) R^(D9) R^(D235) L_(C812) R^(D236) R^(D236) L_(C920) R^(D1) R^(D236) L_(C1028) R^(D4) R^(D236) L_(C1136) R^(D9) R^(D236) L_(C813) R^(D237) R^(D237) L_(C921) R^(D1) R^(D237) L_(C1029) R^(D4) R^(D237) L_(C1137) R^(D9) R^(D237) L_(C814) R^(D238) R^(D238) L_(C922) R^(D1) R^(D238) L_(C1030) R^(D4) R^(D238) L_(C1138) R^(D9) R^(D238) L_(C815) R^(D239) R^(D239) L_(C923) R^(D1) R^(D239) L_(C1031) R^(D4) R^(D239) L_(C1139) R^(D9) R^(D239) L_(C816) R^(D240) R^(D240) L_(C924) R^(D1) R^(D240) L_(C1032) R^(D4) R^(D240) L_(C1140) R^(D9) R^(D240) L_(C817) R^(D241) R^(D241) L_(C925) R^(D1) R^(D241) L_(C1033) R^(D4) R^(D241) L_(C1141) R^(D9) R^(D241) L_(C818) R^(D242) R^(D242) L_(C926) R^(D1) R^(D242) L_(C1034) R^(D4) R^(D242) L_(C1142) R^(D9) R^(D242) L_(C819) R^(D243) R^(D243) L_(C927) R^(D1) R^(D243) L_(C1035) R^(D4) R^(D243) L_(C1143) R^(D9) R^(D243) L_(C820) R^(D244) R^(D244) L_(C928) R^(D1) R^(D244) L_(C1036) R^(D4) R^(D244) L_(C1144) R^(D9) R^(D244) L_(C821) R^(D245) R^(D245) L_(C929) R^(D1) R^(D245) L_(C1037) R^(D4) R^(D245) L_(C1145) R^(D9) R^(D245) L_(C822) R^(D246) R^(D246) L_(C930) R^(D1) R^(D246) L_(C1038) R^(D4) R^(D246) L_(C1146) R^(D9) R^(D246) L_(C823) R^(D17) R^(D193) L_(C931) R^(D50) R^(D193) L_(C1039) R^(D145) R^(D193) L_(C1147) R^(D168) R^(D193) L_(C824) R^(D17) R^(D194) L_(C932) R^(D50) R^(D194) L_(C1040) R^(D145) R^(D194) L_(C1148) R^(D168) R^(D194) L_(C825) R^(D17) R^(D195) L_(C933) R^(D50) R^(D195) L_(C1041) R^(D145) R^(D195) L_(C1149) R^(D168) R^(D195) L_(C826) R^(D17) R^(D196) L_(C934) R^(D50) R^(D196) L_(C1042) R^(D145) R^(D196) L_(C1150) R^(D168) R^(D196) L_(C827) R^(D17) R^(D197) L_(C935) R^(D50) R^(D197) L_(C1043) R^(D145) R^(D197) L_(C1151) R^(D168) R^(D197) L_(C828) R^(D17) R^(D198) L_(C936) R^(D50) R^(D198) L_(C1044) R^(D145) R^(D198) L_(C1152) R^(D168) R^(D198) L_(C829) R^(D17) R^(D199) L_(C937) R^(D50) R^(D199) L_(C1045) R^(D145) R^(D199) L_(C1153) R^(D168) R^(D199) L_(C830) R^(D17) R^(D200) L_(C938) R^(D50) R^(D200) L_(C1046) R^(D145) R^(D200) L_(C1154) R^(D168) R^(D200) L_(C831) R^(D17) R^(D201) L_(C939) R^(D50) R^(D201) L_(C1047) R^(D145) R^(D201) L_(C1155) R^(D168) R^(D201) L_(C832) R^(D17) R^(D202) L_(C940) R^(D50) R^(D202) L_(C1048) R^(D145) R^(D202) L_(C1156) R^(D168) R^(D202) L_(C833) R^(D17) R^(D203) L_(C941) R^(D50) R^(D203) L_(C1049) R^(D145) R^(D203) L_(C1157) R^(D168) R^(D203) L_(C834) R^(D17) R^(D204) L_(C942) R^(D50) R^(D204) L_(C1050) R^(D145) R^(D204) L_(C1158) R^(D168) R^(D204) L_(C835) R^(D17) R^(D205) L_(C943) R^(D50) R^(D205) L_(C1051) R^(D145) R^(D205) L_(C1159) R^(D168) R^(D205) L_(C836) R^(D17) R^(D206) L_(C944) R^(D50) R^(D206) L_(C1052) R^(D145) R^(D206) L_(C1160) R^(D168) R^(D206) L_(C837) R^(D17) R^(D207) L_(C945) R^(D50) R^(D207) L_(C1053) R^(D145) R^(D207) L_(C1161) R^(D168) R^(D207) L_(C838) R^(D17) R^(D208) L_(C946) R^(D50) R^(D208) L_(C1054) R^(D145) R^(D208) L_(C1162) R^(D168) R^(D208) L_(C839) R^(D17) R^(D209) L_(C947) R^(D50) R^(D209) L_(C1055) R^(D145) R^(D209) L_(C1163) R^(D168) R^(D209) L_(C840) R^(D17) R^(D210) L_(C948) R^(D50) R^(D210) L_(C1056) R^(D145) R^(D210) L_(C1164) R^(D168) R^(D210) L_(C841) R^(D17) R^(D211) L_(C949) R^(D50) R^(D211) L_(C1057) R^(D145) R^(D211) L_(C1165) R^(D168) R^(D211) L_(C842) R^(D17) R^(D212) L_(C950) R^(D50) R^(D212) L_(C1058) R^(D145) R^(D212) L_(C1166) R^(D168) R^(D212) L_(C843) R^(D17) R^(D213) L_(C951) R^(D50) R^(D213) L_(C1059) R^(D145) R^(D213) L_(C1167) R^(D168) R^(D213) L_(C844) R^(D17) R^(D214) L_(C952) R^(D50) R^(D214) L_(C1060) R^(D145) R^(D214) L_(C1168) R^(D168) R^(D214) L_(C845) R^(D17) R^(D215) L_(C953) R^(D50) R^(D215) L_(C1061) R^(D145) R^(D215) L_(C1169) R^(D168) R^(D215) L_(C846) R^(D17) R^(D216) L_(C954) R^(D50) R^(D216) L_(C1062) R^(D145) R^(D216) L_(C1170) R^(D168) R^(D216) L_(C847) R^(D17) R^(D217) L_(C955) R^(D50) R^(D217) L_(C1063) R^(D145) R^(D217) L_(C1171) R^(D168) R^(D217) L_(C848) R^(D17) R^(D218) L_(C956) R^(D50) R^(D218) L_(C1064) R^(D145) R^(D218) L_(C1172) R^(D168) R^(D218) L_(C849) R^(D17) R^(D219) L_(C957) R^(D50) R^(D219) L_(C1065) R^(D145) R^(D219) L_(C1173) R^(D168) R^(D219) L_(C850) R^(D17) R^(D220) L_(C958) R^(D50) R^(D220) L_(C1066) R^(D145) R^(D220) L_(C1174) R^(D168) R^(D220) L_(C851) R^(D17) R^(D221) L_(C959) R^(D50) R^(D221) L_(C1067) R^(D145) R^(D221) L_(C1175) R^(D168) R^(D221) L_(C852) R^(D17) R^(D222) L_(C960) R^(D50) R^(D222) L_(C1068) R^(D145) R^(D222) L_(C1176) R^(D168) R^(D222) L_(C853) R^(D17) R^(D223) L_(C961) R^(D50) R^(D223) L_(C1069) R^(D145) R^(D223) L_(C1177) R^(D168) R^(D223) L_(C854) R^(D17) R^(D224) L_(C962) R^(D50) R^(D224) L_(C1070) R^(D145) R^(D224) L_(C1178) R^(D168) R^(D224) L_(C855) R^(D17) R^(D225) L_(C963) R^(D50) R^(D225) L_(C1071) R^(D145) R^(D225) L_(C1179) R^(D168) R^(D225) L_(C856) R^(D17) R^(D226) L_(C964) R^(D50) R^(D226) L_(C1072) R^(D145) R^(D226) L_(C1180) R^(D168) R^(D226) L_(C857) R^(D17) R^(D227) L_(C965) R^(D50) R^(D227) L_(C1073) R^(D145) R^(D227) L_(C1181) R^(D168) R^(D227) L_(C858) R^(D17) R^(D228) L_(C966) R^(D50) R^(D228) L_(C1074) R^(D145) R^(D228) L_(C1182) R^(D168) R^(D228) L_(C859) R^(D17) R^(D229) L_(C967) R^(D50) R^(D229) L_(C1075) R^(D145) R^(D229) L_(C1183) R^(D168) R^(D229) L_(C860) R^(D17) R^(D230) L_(C968) R^(D50) R^(D230) L_(C1076) R^(D145) R^(D230) L_(C1184) R^(D168) R^(D230) L_(C861) R^(D17) R^(D231) L_(C969) R^(D50) R^(D231) L_(C1077) R^(D145) R^(D231) L_(C1185) R^(D168) R^(D231) L_(C862) R^(D17) R^(D232) L_(C970) R^(D50) R^(D232) L_(C1078) R^(D145) R^(D232) L_(C1186) R^(D168) R^(D232) L_(C863) R^(D17) R^(D233) L_(C971) R^(D50) R^(D233) L_(C1079) R^(D145) R^(D233) L_(C1187) R^(D168) R^(D233) L_(C864) R^(D17) R^(D234) L_(C972) R^(D50) R^(D234) L_(C1080) R^(D145) R^(D234) L_(C1188) R^(D168) R^(D234) L_(C865) R^(D17) R^(D235) L_(C973) R^(D50) R^(D235) L_(C1081) R^(D145) R^(D235) L_(C1189) R^(D168) R^(D235) L_(C866) R^(D17) R^(D236) L_(C974) R^(D50) R^(D236) L_(C1082) R^(D145) R^(D236) L_(C1190) R^(D168) R^(D236) L_(C867) R^(D17) R^(D237) L_(C975) R^(D50) R^(D237) L_(C1083) R^(D145) R^(D237) L_(C1191) R^(D168) R^(D237) L_(C868) R^(D17) R^(D238) L_(C976) R^(D50) R^(D238) L_(C1084) R^(D145) R^(D238) L_(C1192) R^(D168) R^(D238) L_(C869) R^(D17) R^(D239) L_(C977) R^(D50) R^(D239) L_(C1085) R^(D145) R^(D239) L_(C1193) R^(D168) R^(D239) L_(C870) R^(D17) R^(D240) L_(C978) R^(D50) R^(D240) L_(C1086) R^(D145) R^(D240) L_(C1194) R^(D168) R^(D240) L_(C871) R^(D17) R^(D241) L_(C979) R^(D50) R^(D241) L_(C1087) R^(D145) R^(D241) L_(C1195) R^(D168) R^(D241) L_(C872) R^(D17) R^(D242) L_(C980) R^(D50) R^(D242) L_(C1088) R^(D145) R^(D242) L_(C1196) R^(D168) R^(D242) L_(C873) R^(D17) R^(D243) L_(C981) R^(D50) R^(D243) L_(C1089) R^(D145) R^(D243) L_(C1197) R^(D168) R^(D243) L_(C874) R^(D17) R^(D244) L_(C982) R^(D50) R^(D244) L_(C1090) R^(D145) R^(D244) L_(C1198) R^(D168) R^(D244) L_(C875) R^(D17) R^(D245) L_(C983) R^(D50) R^(D245) L_(C1091) R^(D145) R^(D245) L_(C1199) R^(D168) R^(D245) L_(C876) R^(D17) R^(D246) L_(C984) R^(D50) R^(D246) L_(C1092) R^(D145) R^(D246) L_(C1200) R^(D168) R^(D246) L_(C1201) R^(D10) R^(D193) L_(C1255) R^(D55) R^(D193) L_(C1309) R^(D37) R^(D193) L_(C1363) R^(D143) R^(D193) L_(C1202) R^(D10) R^(D194) L_(C1256) R^(D55) R^(D194) L_(C1310) R^(D37) R^(D194) L_(C1364) R^(D143) R^(D194) L_(C1203) R^(D10) R^(D195) L_(C1257) R^(D55) R^(D195) L_(C1311) R^(D37) R^(D195) L_(C1365) R^(D143) R^(D195) L_(C1204) R^(D10) R^(D196) L_(C1258) R^(D55) R^(D196) L_(C1312) R^(D37) R^(D196) L_(C1366) R^(D143) R^(D196) L_(C1205) R^(D10) R^(D197) L_(C1259) R^(D55) R^(D197) L_(C1313) R^(D37) R^(D197) L_(C1367) R^(D143) R^(D197) L_(C1206) R^(D10) R^(D198) L_(C1260) R^(D55) R^(D198) L_(C1314) R^(D37) R^(D198) L_(C1368) R^(D143) R^(D198) L_(C1207) R^(D10) R^(D199) L_(C1261) R^(D55) R^(D199) L_(C1315) R^(D37) R^(D199) L_(C1369) R^(D143) R^(D199) L_(C1208) R^(D10) R^(D200) L_(C1262) R^(D55) R^(D200) L_(C1316) R^(D37) R^(D200) L_(C1370) R^(D143) R^(D200) L_(C1209) R^(D10) R^(D201) L_(C1263) R^(D55) R^(D201) L_(C1317) R^(D37) R^(D201) L_(C1371) R^(D143) R^(D201) L_(C1210) R^(D10) R^(D202) L_(C1264) R^(D55) R^(D202) L_(C1318) R^(D37) R^(D202) L_(C1372) R^(D143) R^(D202) L_(C1211) R^(D10) R^(D203) L_(C1265) R^(D55) R^(D203) L_(C1319) R^(D37) R^(D203) L_(C1373) R^(D143) R^(D203) L_(C1212) R^(D10) R^(D204) L_(C1266) R^(D55) R^(D204) L_(C1320) R^(D37) R^(D204) L_(C1374) R^(D143) R^(D204) L_(C1213) R^(D10) R^(D205) L_(C1267) R^(D55) R^(D205) L_(C1321) R^(D37) R^(D205) L_(C1375) R^(D143) R^(D205) L_(C1214) R^(D10) R^(D206) L_(C1268) R^(D55) R^(D206) L_(C1322) R^(D37) R^(D206) L_(C1376) R^(D143) R^(D206) L_(C1215) R^(D10) R^(D207) L_(C1269) R^(D55) R^(D207) L_(C1323) R^(D37) R^(D207) L_(C1377) R^(D143) R^(D207) L_(C1216) R^(D10) R^(D208) L_(C1270) R^(D55) R^(D208) L_(C1324) R^(D37) R^(D208) L_(C1378) R^(D143) R^(D208) L_(C1217) R^(D10) R^(D209) L_(C1271) R^(D55) R^(D209) L_(C1325) R^(D37) R^(D209) L_(C1379) R^(D143) R^(D209) L_(C1218) R^(D10) R^(D210) L_(C1272) R^(D55) R^(D210) L_(C1326) R^(D37) R^(D210) L_(C1380) R^(D143) R^(D210) L_(C1219) R^(D10) R^(D211) L_(C1273) R^(D55) R^(D211) L_(C1327) R^(D37) R^(D211) L_(C1381) R^(D143) R^(D211) L_(C1220) R^(D10) R^(D212) L_(C1274) R^(D55) R^(D212) L_(C1328) R^(D37) R^(D212) L_(C1382) R^(D143) R^(D212) L_(C1221) R^(D10) R^(D213) L_(C1275) R^(D55) R^(D213) L_(C1329) R^(D37) R^(D213) L_(C1383) R^(D143) R^(D213) L_(C1222) R^(D10) R^(D214) L_(C1276) R^(D55) R^(D214) L_(C1330) R^(D37) R^(D214) L_(C1384) R^(D143) R^(D214) L_(C1223) R^(D10) R^(D215) L_(C1277) R^(D55) R^(D215) L_(C1331) R^(D37) R^(D215) L_(C1385) R^(D143) R^(D215) L_(C1224) R^(D10) R^(D216) L_(C1278) R^(D55) R^(D216) L_(C1332) R^(D37) R^(D216) L_(C1386) R^(D143) R^(D216) L_(C1225) R^(D10) R^(D217) L_(C1279) R^(D55) R^(D217) L_(C1333) R^(D37) R^(D217) L_(C1387) R^(D143) R^(D217) L_(C1226) R^(D10) R^(D218) L_(C1280) R^(D55) R^(D218) L_(C1334) R^(D37) R^(D218) L_(C1388) R^(D143) R^(D218) L_(C1227) R^(D10) R^(D219) L_(C1281) R^(D55) R^(D219) L_(C1335) R^(D37) R^(D219) L_(C1389) R^(D143) R^(D219) L_(C1228) R^(D10) R^(D220) L_(C1282) R^(D55) R^(D220) L_(C1336) R^(D37) R^(D220) L_(C1390) R^(D143) R^(D220) L_(C1229) R^(D10) R^(D221) L_(C1283) R^(D55) R^(D221) L_(C1337) R^(D37) R^(D221) L_(C1391) R^(D143) R^(D221) L_(C1230) R^(D10) R^(D222) L_(C1284) R^(D55) R^(D222) L_(C1338) R^(D37) R^(D222) L_(C1392) R^(D143) R^(D222) L_(C1231) R^(D10) R^(D223) L_(C1285) R^(D55) R^(D223) L_(C1339) R^(D37) R^(D223) L_(C1393) R^(D143) R^(D223) L_(C1232) R^(D10) R^(D224) L_(C1286) R^(D55) R^(D224) L_(C1340) R^(D37) R^(D224) L_(C1394) R^(D143) R^(D224) L_(C1233) R^(D10) R^(D225) L_(C1287) R^(D55) R^(D225) L_(C1341) R^(D37) R^(D225) L_(C1395) R^(D143) R^(D225) L_(C1234) R^(D10) R^(D226) L_(C1288) R^(D55) R^(D226) L_(C1342) R^(D37) R^(D226) L_(C1396) R^(D143) R^(D226) L_(C1235) R^(D10) R^(D227) L_(C1289) R^(D55) R^(D227) L_(C1343) R^(D37) R^(D227) L_(C1397) R^(D143) R^(D227) L_(C1236) R^(D10) R^(D228) L_(C1290) R^(D55) R^(D228) L_(C1344) R^(D37) R^(D228) L_(C1398) R^(D143) R^(D228) L_(C1237) R^(D10) R^(D229) L_(C1291) R^(D55) R^(D229) L_(C1345) R^(D37) R^(D229) L_(C1399) R^(D143) R^(D229) L_(C1238) R^(D10) R^(D230) L_(C1292) R^(D55) R^(D230) L_(C1346) R^(D37) R^(D230) L_(C1400) R^(D143) R^(D230) L_(C1239) R^(D10) R^(D231) L_(C1293) R^(D55) R^(D231) L_(C1347) R^(D37) R^(D231) L_(C1401) R^(D143) R^(D231) L_(C1240) R^(D10) R^(D232) L_(C1294) R^(D55) R^(D232) L_(C1348) R^(D37) R^(D232) L_(C1402) R^(D143) R^(D232) L_(C1241) R^(D10) R^(D233) L_(C1295) R^(D55) R^(D233) L_(C1349) R^(D37) R^(D233) L_(C1403) R^(D143) R^(D233) L_(C1242) R^(D10) R^(D234) L_(C1296) R^(D55) R^(D234) L_(C1350) R^(D37) R^(D234) L_(C1404) R^(D143) R^(D234) L_(C1243) R^(D10) R^(D235) L_(C1297) R^(D55) R^(D235) L_(C1351) R^(D37) R^(D235) L_(C1405) R^(D143) R^(D235) L_(C1244) R^(D10) R^(D236) L_(C1298) R^(D55) R^(D236) L_(C1352) R^(D37) R^(D236) L_(C1406) R^(D143) R^(D236) L_(C1245) R^(D10) R^(D237) L_(C1299) R^(D55) R^(D237) L_(C1353) R^(D37) R^(D237) L_(C1407) R^(D143) R^(D237) L_(C1246) R^(D10) R^(D238) L_(C1300) R^(D55) R^(D238) L_(C1354) R^(D37) R^(D238) L_(C1408) R^(D143) R^(D238) L_(C1247) R^(D10) R^(D239) L_(C1301) R^(D55) R^(D239) L_(C1355) R^(D37) R^(D239) L_(C1409) R^(D143) R^(D239) L_(C1248) R^(D10) R^(D240) L_(C1302) R^(D55) R^(D240) L_(C1356) R^(D37) R^(D240) L_(C1410) R^(D143) R^(D240) L_(C1249) R^(D10) R^(D241) L_(C1303) R^(D55) R^(D241) L_(C1357) R^(D37) R^(D241) L_(C1411) R^(D143) R^(D241) L_(C1250) R^(D10) R^(D242) L_(C1304) R^(D55) R^(D242) L_(C1358) R^(D37) R^(D242) L_(C1412) R^(D143) R^(D242) L_(C1251) R^(D10) R^(D243) L_(C1305) R^(D55) R^(D243) L_(C1359) R^(D37) R^(D243) L_(C1413) R^(D143) R^(D243) L_(C1252) R^(D10) R^(D244) L_(C1306) R^(D55) R^(D244) L_(C1360) R^(D37) R^(D244) L_(C1414) R^(D143) R^(D244) L_(C1253) R^(D10) R^(D245) L_(C1307) R^(D55) R^(D245) L_(C1361) R^(D37) R^(D245) L_(C1415) R^(D143) R^(D245) L_(C1254) R^(D10) R^(D246) L_(C1308) R^(D55) R^(D246) L_(C1362) R^(D37) R^(D246) L_(C1416) R^(D143) R^(D246)

wherein R^(D1) to R^(D246) have the following structures:


15. The compound of claim 12, wherein the compound is selected from the group consisting of:


16. The compound of claim 12, wherein the compound has a structure of

wherein: M¹ is Pd or Pt; each of moieties of E and F is independently monocyclic or polycyclic ring structure comprising 5-membered and/or 6-membered carbocyclic or heterocyclic rings; Z³ and Z⁴ are each independently C or N; K¹, K², K³, and K⁴ are each independently selected from the group consisting of a direct bond, O, and S, wherein at least two of K¹, K², K³, and K⁴ are direct bonds; L¹, L², and L³ are each independently selected from the group consisting of a single bond, absent a bond, O, S, SO, SO₂, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, and NR, wherein at least one of L¹ and L² is present; X⁵-X⁷ are each independently C or N; R^(E) and R^(F) each independently represent zero, mono, or up to a maximum allowed number of substitutions to its associated ring; each of R^(E), and R^(F) is independently a hydrogen or a substituent selected from the group consisting of deuterium, fluorine, alkyl, cycloalkyl, heteroalkyl, alkoxy, aryloxy, amino, silyl, boryl, alkenyl, cycloalkenyl, heteroalkenyl, aryl, heteroaryl, nitrile, isonitrile, sulfanyl, and combinations thereof; and two adjacent R, R′, R^(A), R^(B), R^(C), R^(D), R^(E), or R^(F) can be joined or fused together to form a ring where chemically feasible.
 17. An organic light emitting device (OLED) comprising: an anode; a cathode; and an organic layer disposed between the anode and the cathode, wherein the organic layer comprises a compound comprising a ligand L_(A) having a structure of

wherein: one of Z¹ and Z² is C and the other is N; each of K¹ or K² is independently a direct bond, O, or S; moiety B, moiety C, and moiety D are each independently monocyclic or polycyclic ring structure containing 5-membered or 6-membered carbocyclic or heterocyclic rings; X¹-X⁴ are each independently C or N, with at least one of X¹ or X² being N if both moiety B and moiety C of Formula I are monocyclic 6-membered aromatic rings; Y is selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; W is selected from the group consisting of O, S, S═O, SO₂, NR, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, GeRR′, PR, P═O, and P═S; each of R^(A), R^(B), R^(C), and R^(D) independently represents zero, mono, or up to a maximum allowed number of substitutions to its associated ring; each of R, R′, R^(A), R^(B), R^(C), and R^(D) is independently a hydrogen or a substituent selected from the group consisting of deuterium, halogen, alkyl, cycloalkyl, heteroalkyl, heterocycloalkyl, arylalkyl, alkoxy, aryloxy, amino, silyl, germyl, boryl, selenyl, alkenyl, cycloalkenyl, heteroalkenyl, alkynyl, aryl, heteroaryl, acyl, carboxylic acid, ether, ester, nitrile, isonitrile, sulfanyl, sulfinyl, sulfonyl, phosphino, and combinations thereof; and any two adjacent R, R′, R^(A), R^(B), R^(C), or R^(D) can be joined or fused together to form a ring, wherein the ligand L_(A) is coordinated to a metal M by the two indicated dashed lines; wherein M is selected from the group consisting of Ru, Os, Ir, Pd, Pt, Cu, Ag, and Au; and wherein the ligand L_(A) can be joined with other ligands to form a tridentate, tetradentate, pentadentate, or hexadentate ligand.
 18. The OLED of claim 17, wherein the organic layer further comprises a host, wherein host comprises at least one chemical moiety selected from the group consisting of triphenylene, carbazole, indolocarbazole, dibenzothiophene, dibenzofuran, dibenzoselenophene, 5,9-dioxa-13b-boranaphtho[3,2,1-de]anthracene, aza-triphenylene, aza-carbazole, aza-indolocarbazole, aza-dibenzothiophene, aza-dibenzofuran, aza-dibenzoselenophene, and aza-(5,9-dioxa-13b-boranaphtho[3,2,1-de]anthracene).
 19. The OLED of claim 18, wherein the host is selected from the group consisting of:

and combinations thereof.
 20. A consumer product comprising an organic light-emitting device (OLED) comprising: an anode; a cathode; and an organic layer disposed between the anode and the cathode, wherein the organic layer comprises a compound comprising a ligand L_(A) having a structure of

wherein: one of Z¹ and Z² is C and the other is N; each of K¹ or K² is independently a direct bond, O, or S; moiety B, moiety C, and moiety D are each independently monocyclic or polycyclic ring structure containing 5-membered or 6-membered carbocyclic or heterocyclic rings; X¹-X⁴ are each independently C or N, with at least one of X¹ or X² being N if both moiety B and moiety C of Formula I are monocyclic 6-membered aromatic rings; Y is selected from the group consisting of O, S, Se, NR, CRR′, BR, BRR′, SiRR′, and GeRR′; W is selected from the group consisting of O, S, S═O, SO₂, NR, C═O, C═CRR′, CRR′, SiRR′, BR, BRR′, GeRR′, PR, P═O, and P═S; each of R^(A), R^(B), R^(C), and R^(D) independently represents zero, mono, or up to a maximum allowed number of substitutions to its associated ring; each of R, R′, R^(A), R^(B), R^(C), and R^(D) is independently a hydrogen or a substituent selected from the group consisting of deuterium, halogen, alkyl, cycloalkyl, heteroalkyl, heterocycloalkyl, arylalkyl, alkoxy, aryloxy, amino, silyl, germyl, boryl, selenyl, alkenyl, cycloalkenyl, heteroalkenyl, alkynyl, aryl, heteroaryl, acyl, carboxylic acid, ether, ester, nitrile, isonitrile, sulfanyl, sulfinyl, sulfonyl, phosphino, and combinations thereof; and any two adjacent R, R′, R^(A), R^(B), R^(C), or R^(D) can be joined or fused together to form a ring, wherein the ligand L_(A) is coordinated to a metal M by the two indicated dashed lines; wherein M is selected from the group consisting of Ru, Os, Ir, Pd, Pt, Cu, Ag, and Au; and wherein the ligand L_(A) can be joined with other ligands to form a tridentate, tetradentate, pentadentate, or hexadentate ligand. 